Dna plasmids with improved expression

ABSTRACT

The present invention relates to the production and use of covalently closed circular (ccc) recombinant plasmids, and more particularly to vector modifications that improve expression of said DNA molecules in the target organism.

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims priority to U.S. Provisional Patent Application Ser. No. 61/743,219, entitled “DNA Plasmids With Improved Expression” which was filed Aug. 29, 2012, the entire contents of which are incorporated herein by reference.

STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT

This invention was supported in part with government support under Grant No. R44GM080768, awarded by the National Institutes of Health. The government has certain rights in this invention.

FIELD OF THE INVENTION

The present invention relates to a family of eukaryotic expression plasmids useful for gene therapy, obtaining improved genetic immunization, natural interferon production, and more particularly, for improving the expression of plasmid encoded antigens, therapeutic proteins and RNAs.

The present invention also relates to the production of covalently closed circular (ccc) recombinant DNA molecules such as plasmids, cosmids, bacterial artificial chromosomes (BACs), bacteriophages, viral vectors and hybrids thereof, and more particularly to strain modifications that improve production yield of said DNA molecules in fermentation culture.

Such recombinant DNA molecules are useful in biotechnology, transgenic organisms, gene therapy, therapeutic vaccination, agriculture and DNA vaccines.

BACKGROUND OF THE INVENTION

E. coli plasmids have long been an important source of recombinant DNA molecules used by researchers and by industry. Today, plasmid DNA is becoming increasingly important as the next generation of biotechnology products (e.g., gene medicines and DNA vaccines) make their way into clinical trials, and eventually into the pharmaceutical marketplace. Plasmid DNA vaccines may find application as preventive vaccines for viral, bacterial, or parasitic diseases; immunizing agents for the preparation of hyper immune globulin products; therapeutic vaccines for infectious diseases; or as cancer vaccines. Plasmids are also utilized in gene therapy or gene replacement applications, wherein the desired gene product is expressed from the plasmid after administration to the patient.

Therapeutic plasmids often contain a pMB1, ColE1 or pBR322 derived replication origin. Common high copy number derivatives have mutations affecting copy number regulation, such as ROP (Repressor of primer gene) deletion, with a second site mutation that increases copy number (e.g. pMB1 pUC G to A point mutation, or ColE1 pMM1). Higher temperature (42° C.) can be employed to induce selective plasmid amplification with pUC and pMM1 replication origins.

U.S. Pat. No. 7,943,377 (Carnes, A E and Williams, J A, 2011) disclose methods for fed-batch fermentation, in which plasmid-containing E. coli cells were grown at a reduced temperature during part of the fed-batch phase, during which growth rate was restricted, followed by a temperature up-shift and continued growth at elevated temperature in order to accumulate plasmid; the temperature shift at restricted growth rate improved yield and purity of plasmid. Other fermentation processes for plasmid production are described in Carnes A. E. 2005 BioProcess Intl; 3:36-44, which is incorporated herein by reference in its entirety.

The art teaches that one of the limitations of application of plasmid therapies and plasmid vaccines is regulatory agency (e.g. Food and Drug Administration, EMEC) safety concerns regarding 1) plasmid transfer and replication in endogenous bacterial flora, or 2) plasmid encoded selection marker expression in human cells, or endogenous bacterial flora. Additionally, regulatory agency guidances recommend removal of all non essential sequences in a vector. Plasmids containing a pMB1, ColE1 or pBR322 derived replication origin can replicate promiscuously in E. coli hosts. This presents a safety concern that a plasmid therapeutic gene or antigen will be transferred and replicated to a patient's endogenous flora. Ideally, a therapeutic or vaccine plasmid would be replication incompetent in endogenous E. coli strains. This requires replacement of the pMB1, ColE1 or pBR322 derived replication origin with a conditional replication origin that requires a specialized cell line for propagation. As well, regulatory agencies such as the EMEA and FDA are concerned with utilization of antibiotic resistance or alternative protein markers in gene therapy and gene vaccine vectors, due to concerns that the gene (antibiotic resistance marker or protein marker) may be expressed in a patients cells. Ideally, plasmid therapies and plasmid vaccines would be 1) replication incompetent in endogenous E. coli strains, 2) would not encode a protein based selection marker and 3) be minimalized to eliminate all non essential sequences.

The art further teaches that one of the limitations of application of plasmid therapies and vaccines is that antigen expression is generally very low. Vector modifications that improve antigen expression (e.g. codon optimization of the gene, inclusion of an intron, use of the strong constitutive CMV or CAGG promoters versus weaker or cell line specific promoter) are highly correlative with improved in vivo expression and, where applicable, immune responses (reviewed in Manoj S, Babiuk L A, van Drunen Little-van den Hurk S. 2004 Crit Rev Clin Lab Sci 41: 1-39). A hybrid CMV promoter (CMV/R), which increased antigen expression, also improved cellular immune responses to HIV DNA vaccines in mice and nonhuman primates (Barouch D H, Yang Z Y, Kong W P, Korioth-Schmitz B, Sumida S M, Truitt D M, Kishko M G, Arthur J C, Miura A, Mascola J R, Letvin N L, Nabel G J. 2005 J Virol. 79: 8828-8834). A plasmid containing the woodchuck hepatitis virus posttranscriptional regulatory element (a 600 bp element that increases stability and extranuclear transport of RNA resulting in enhanced levels of mRNA for translation) enhanced antigen expression and protective immunity to influenza hemagglutinin (HA) in mice (Garg S, Oran A E, Hon H, Jacob J. 2004 J Immunol. 173: 550-558). These studies teach that improvement in expression beyond that of current CMV based vectors may generally improve immunogenicity and, in the case of gene therapeutics, efficacy.

SUMMARY OF THE INVENTION

The present invention relates to a family of minimalized eukaryotic expression plasmids that are replication incompetent in endogenous flora and have dramatically improved in vivo expression. These vectors are useful for gene therapy, genetic immunization and or interferon therapy.

The present invention also relates generally to methods of increasing production yield of covalently closed super-coiled plasmid DNA.

Improved vectors that utilize novel replication origins that unexpectedly improve antigen expression are disclosed.

One object of the invention is to provide improved expression plasmid vectors. Yet another object of the invention is to provide methods for improving plasmid copy number.

According to one object of the invention, a method of increasing expression from an expression plasmid vector comprises modifying the plasmid DNA to replace the pMB1, ColE1 or pBR322 derived replication origin and selectable marker with an alternative replication origin selected from the group consisting of an minimal pUC origin, a R6K gamma replication origin, a ColE2-P9 replication origin, and a ColE2-P9 related replication origin and an RNA selectable marker; transforming the modified plasmid DNA into a bacterial cell line rendered competent for transformation; and isolating the resultant transformed bacterial cells. The resultant plasmid surprisingly has higher in vivo expression levels than the parent pMB1, ColE1 or pBR322 derived replication origin expression plasmid vector.

According to one object of the invention, a composition for construction of a eukaryotic expression vector comprises an R6K origin with at least 90% sequence identity to the sequence set forth as SEQ ID NO: 1, and a RNA selectable marker, wherein said R6K origin is operably linked to said RNA selectable marker and a eukaryotic region. According to another object of the invention, said R6K origin-RNA selectable marker improves said vector expression in vivo compared to a corresponding vector containing a pMB1, ColE1 or pBR322 derived replication origin. According to still another object of the invention, said vector has at least 95% sequence identity to a sequence selected from the group consisting of: SEQ ID NO: 2, SEQ ID NO: 3, SEQ ID NO:41.

According to one object of the invention, a composition for construction of a eukaryotic expression vector comprises a ColE2-P9 origin with at least 90% sequence identity to the sequence set forth as SEQ ID NO: 4, 5, 6, or 7, and a a RNA selectable marker, wherein said ColE2-P9 origin—a RNA selectable marker is operably linked to a eukaryotic region. According to another object of the invention, said ColE2-P9 origin-RNA selectable marker improves said vector expression in vivo compared to a corresponding vector containing a pMB1, ColE1 or pBR322 derived replication origin. According to still another object of the invention, said vector has at least 95% sequence identity to a sequence selected from the group consisting of: SEQ ID NO: 8, SEQ ID NO: 9. According to still another object of the invention, a primosomal assembly site (ssiA) is optionally incorporated into the vector adjacent to the ColE2-P9 origin.

According to another object of the invention, production cell lines are disclosed that improve plasmid yield in shake flask and or fermentation culture with said R6K gamma replication origin, ColE2-P9 replication origin, or ColE2-P9 related replication origin plasmid vectors of the current invention.

According to another object of the invention, production cell lines providing heat inducible induction of R6K gamma replication origin, ColE2-P9 replication origin, or ColE2-P9 related replication origin plasmid vectors for DNA production are disclosed. These cell lines contain one or more copies of the corresponding R6K gamma replication origin, ColE2-P9 replication origin, or ColE2-P9 related replication protein integrated into the genome and expressed from the group consisting of: the heat inducible P_(L) promoter (SEQ ID NO: 10), the heat inducible P_(L) promoter incorporating the OL1-G deletion (SEQ ID NO: 11), the heat inducible P_(L) promoter incorporating the OL1-G to T substitution (SEQ ID NO: 12).

According to another object of the invention, mutant R6K replication proteins that improve heat inducible induction of R6K gamma replication origin vectors are disclosed. These cell lines contain one or more copies of the mutant R6K gamma replication origin replication protein integrated into the genome and expressed from the group consisting of: the heat inducible P_(L) promoter (SEQ ID NO: 10), the heat inducible P_(L) promoter incorporating the OL1-G deletion (SEQ ID NO: 11), the heat inducible P_(L) promoter incorporating the OL1-G to T substitution (SEQ ID NO: 12). The mutant R6K gamma replication origin replication protein are selected from the group consisting of: P42L-P113S (SEQ ID NO: 13), P42L-P106L-F107S (SEQ ID NO: 14).

According to another object of the invention, a mutant ColE2-P9 replication protein that improve heat inducible induction of ColE2-P9 replication origin vectors is disclosed. These cell lines contain one or more copies of the mutant ColE2-P9 replication origin replication protein integrated into the genome and expressed from the group consisting of: the heat inducible P_(L) promoter (SEQ ID NO: 10), the heat inducible P_(L) promoter incorporating the OL1-G deletion (SEQ ID NO: 11), the heat inducible P_(L) promoter incorporating the OL1-G to T substitution (SEQ ID NO: 12). The mutant ColE2-P9 replication origin replication protein is ColE2-P9 Rep mut G194D (SEQ ID NO: 16).

Further objects and advantages of the invention will become apparent from a consideration of the drawings and ensuing description.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1 depicts the NTC8685 pUC origin expression vector;

FIG. 2 depicts the NTC9685C ColE2 origin expression vector;

FIG. 3 depicts the NTC9685R R6K origin expression vector;

FIG. 4 depicts the NTC9385C ColE2 origin expression vector;

FIG. 5 depicts the NTC9385R R6K origin expression vector;

FIG. 6 depicts the pINT pR pL R6K Rep pi P42L-P106L-F107S (P3-) integration vector;

FIG. 7 depicts the P_(L) promoter with OL1 mutations OL1-G and OL1-G to T;

FIG. 8 depicts the pINT pR pL ColE2 Rep protein integration vector;

FIG. 9 shows Nanoplasmid expression in vitro after lipofectamine transfection of HEK293 cell line;

FIG. 10 shows Nanoplasmid expression in vivo after intramuscular injection with EP;

FIG. 11 depicts a ColE2 origin Nanoplasmid shRNA expression vector; and

FIG. 12 depicts an IncB RNAI based RNA selectable marker.

Table 1: P_(L) promoter with OL1 mutations OL1-G and OL1-G to T improve plasmid yields in HyperGRO fermentation Table 2: NTC9385R-EGFP LB media shake flask production yields in R6K production strains Table 3: NTC9385C-Luc plasmid performance in different processes and production cell lines Table 4: ColE2 Origin EGFP vector production in NTC701131 ColE2 production cell line Table 5: NTC9382C, NTC9385C, NTC9382R, NTC9385R, NTC9682C, NTC9685C, NTC9682R, and NTC9685R vectors Table 6: gWIZ and NTC9385C Nanoplasmid expression compared to NTC8685 Table 7: SR vector expression in vitro and in vivo Table 8: RNA Pol III Nanoplasmid vector expression Table 9: High level expression is obtained with pMB1 RNAI or RNA-OUT antisense RNA vectors SEQ ID NO:1: R6K gamma Origin SEQ ID NO:2: NTC9385R vector backbone SEQ ID NO:3: NTC9685R vector backbone

SEQ ID NO:4: ColE2 Origin (+7)

SEQ ID NO:5: ColE2 Origin (+7, CpG free)

SEQ ID NO:6: ColE2 Origin (Min) SEQ ID NO:7: ColE2 Origin (+16)

SEQ ID NO:8: NTC9385C vector backbone SEQ ID NO:9: NTC9685C vector backbone

SEQ ID NO:10: P_(L) Promoter (−35 to −10) SEQ ID NO:11: P_(L) Promoter OL1-G (−35 to −10) SEQ ID NO:12: P_(L) Promoter OL1-G to T(−35 to −10)

SEQ ID NO:13: R6K Rep protein P42L-P113S SEQ ID NO:14: R6K Rep protein P42L-P106L-F107S SEQ ID NO:15: ColE2 Rep protein (wild type) SEQ ID NO:16: ColE2 Rep protein mut (G194D) SEQ ID NO:17: pINT pR pL R6K Rep piP42L-P106L-F107S (P3-) SEQ ID NO:18: pINT pR pL ColE2 Rep protein mut (G194D) SEQ ID NO:19: NTC9385R and NTC9685R Bacterial region. [NheI site-trpA terminator-R6K Origin-RNA-OUT-KpnI site] SEQ ID NO:20: NTC9385C and NTC9685C Bacterial region. [NheI site-ssiA-ColE2 Origin (+7)-RNA-OUT-KpnI site] SEQ ID NO:21: NTC9385C and NTC9685C CpG free ssiA [from plasmid R6K] SEQ ID NO:22: CpG free R6K origin SEQ ID NO:23: RNA-OUT selectable marker from NTC9385C, NTC9685C, NTC9385R, and NTC9685R SEQ ID NO:24: RNA-OUT Sense strand RNA from NTC9385C, NTC9685C, NTC9385R, NTC9685R, and NTC9385Ra SEQ ID NO:25: TPA secretion sequence SEQ ID NO:26: PCR primer 15061101 SEQ ID NO:27: PCR primer 15061102 SEQ ID NO:28: ColE2 core replication origin SEQ ID NO:29: +7(CpG free)-ssiA ColE2 origin SEQ ID NO:30: HTLV-IR-Rabbit β globin hybrid intron SEQ ID NO:31: pMB1 RNAI antisense repressor RNA (origin antisense partner of RNAII) SEQ ID NO:32: pMB1 RNAI selectable Marker, RNAI RNA (Sense strand) SEQ ID NO:33: IncB RNAI antisense repressor RNA (IncB plasmid origin RNAII antisense partner) SEQ ID NO:34: IncB RNAI selectable Marker. DraIII-KpnI restriction fragment SEQ ID NO:35: IncB RNAH-SacB. PstI-MamI restriction fragment SEQ ID NO:36: CpG free RNA-OUT selection marker—flanked by KpnI and BglII-EcoRI sites SEQ ID NO:37: CpG free R6K gamma—RNA-OUT bacterial region (CpG free R6K origin-CpG free RNA-OUT selection marker)—flanked by EcoRI-SphI and BglII-EcoRI sites SEQ ID NO:38: CpG free ColE2 bacterial region (CpG free ssiA-CpG free ColE2 origin-CpG free RNA-OUT selection marker)-flanked by EcoRI-SphI and BglII-EcoRI sites SEQ ID NO:39: NTC9385Ra-02 vector backbone SEQ ID NO:40: NTC9385Ra-01 vector backbone SEQ ID NO:41: NTC9385R-BE vector backbone SEQ ID NO:42: P_(min) minimal pUC replication origin SEQ ID NO:43: pUC (0.85) Bacterial region [NheI site-trpA terminator-P_(min) pUC replication origin (minimal)-RNA-OUT-KpnI site]

DEFINITION OF TERMS

A₄₀₅: Absorbance at 405 nanometers

AF: Antibiotic-free

APC: Antigen Processing Cell, for example, langerhans cells, plasmacytoid or conventional dendritic cells Approximately: As used herein, the term “approximately” or “about,” as applied to one or more values of interest, refers to a value that is the same or similar to a stated reference value BAC: Bacterial artificial chromosome Bacterial region: Region of a plasmid vector required for propagation and selection in the bacterial host BE: Boundary element: Eukaryotic sequence that that blocks the interaction between enhancers and promoters. Also referred to as insulator element. An example is the AT-rich unique region upstream of the CMV enhancer Spel site that can function as an insulator/boundary element (Angulo A, Kerry D, Huang H, Borst E M, Razinsky A, Wu J et al. 2000 J Virol 74: 2826-2839) bp: basepairs

ccc: Covalently Closed Circular

cI: Lambda repressor cITs857: Lambda repressor further incorporating a C to T (Ala to Thr) mutation that confers temperature sensitivity. cITs857 is a functional repressor at 28-30° C., but is mostly inactive at 37-42° C. Also called cI857 Cm^(R): Chloramphenicol resistance

cmv: Cytomegalovirus

CMV promoter boundary element: AT-rich region of the human cytomegalovirus (CMV) genome between the UL127 open reading frame and the major immediate-early (MIE) enhancer. Also referred to as unique region (Angulo et al. Supra, 2000) ColE2-P9 replication origin: a region which is specifically recognized by the plasmid-specified Rep protein to initiate DNA replication. Includes but not limited to ColE2-P9 replication origin sequences disclosed in SEQ ID NO:4: ColE2 Origin (+7), SEQ ID NO:5: ColE2 Origin (+7, CpG free), SEQ ID NO:6: ColE2 Origin (Min) and SEQ ID NO:7: ColE2 Origin (+16) and replication functional mutations as disclosed in Yagura et al 2006, J Bacteriol 188:999-1010 included herein by reference ColE2 related replication origin: The ColE2-P9 origin is highly conserved across the ColE2-related plasmid family. Fifteen ColE2 related plasmid members including ColE3 are compared in Hiraga et al 1994, J Bacteriol. 176:7233 and 53 ColE2 related plasmid members including ColE3 are compared in Yagura et al Supra, 2006. These sequences are included herein by reference ColE2-P9 plasmid: a circular duplex DNA molecule of about 7 kb that is maintained at about 10 to 15 copies per host chromosome. The plasmid encodes an initiator protein (Rep protein), which is the only plasmid-specified trans-acting factor essential for ColE2-P9 plasmid replication ColE2-P9 replication origin RNA-OUT bacterial region: Contains a ColE2-P9 replication origin for propagation and the RNA-OUT selection marker. Optionally includes a PAS, for example, the R6K plasmid CpG free ssiA primosomal assembly site (SEQ ID NO:21) or alternative ØX174 type or ABC type primosomal assembly sites, such as those disclosed in Nomura et al 1991 Gene 108:15 ColE2 plasmid: NTC9385C and NTC9685C vectors disclosed herein, as well as modifications and alternative vectors containing a ColE2-P9 replication origin delivery methods: Methods to deliver gene vectors [e.g. poly(lactide-co-glycolide) (PLGA), ISCOMs, liposomes, niosomes, virosomes, chitosan, and other biodegradable polymers, electroporation, piezoelectric permeabilization, sonoporation, ultrasound, corona plasma, plasma facilitated delivery, tissue tolerable plasma, laser microporation, shock wave energy, magnetic fields, contactless magneto-permeabilization, gene gun, microneedles, naked DNA injection, hydrodynamic delivery, high pressure tail vein injection, needle free biojector, liposomes, microparticles, microspheres, nanoparticles, virosomes, bacterial ghosts, bacteria, attenuated bacteria, etc] as known in the art and included herein by reference DNA replicon: A genetic element that can replicate under its own control; examples include plasmids, cosmids, bacterial artificial chromosomes (BACs), bacteriophages, viral vectors and hybrids thereof E. coli: Escherichia coli, a gram negative bacteria EGFP: Enhanced green fluorescent protein

EP: Electroporation

Eukaryotic expression vector: A vector for expression of mRNA, protein antigens, protein therapeutics, shRNA, RNA or microRNA genes in a target organism Eukaryotic region: The region of a plasmid that encodes eukaryotic sequences and/or sequences required for plasmid function in the target organism. This includes the region of a plasmid vector required for expression of one or more transgenes in the target organism including RNA Pol II enhancers, promoters, transgenes and polyA sequences. A eukaryotic region may express protein or RNA genes using one or more RNA Pol II promoters, or express RNA genes using one or more RNA Pol III promoters or encode both RNA Pol II and RNA Pol III expressed genes. Additional functional eukaryotic region sequences include RNA Pol I or RNA Pol III promoters, RNA Pol I or RNA Pol III expressed transgenes or RNAs, transcriptional terminators, S/MARs, boundary elements, etc FU: Fluorescence units g: Gram, kg for kilogram

Hr(s): Hour(s)

HTLV-I R: HTLV-I R 5′ untranslated region (UTR). Sequences and compositions were disclosed in Williams, J A 2008 World Patent Application WO2008153733 and included herein by reference

IM: Intramuscular

immune response: Antigen reactive cellular (e.g. antigen reactive T cells) or antibody (e.g. antigen reactive IgG) responses IncB RNAI: plasmid pMU720 origin encoded RNAI (SEQ ID NO: 33) that represses RNA II regulated targets (Wilson 1W, Siemering K R, Praszkier J, Pittard A J. 1997. J Bacteriol 179:742)

kan: Kanamycin

kanR: Kanamycin Resistance gene

Kd: Kilodalton

kozak sequence: Optimized sequence of consensus DNA sequence gccRccATG (R=G or A) immediately upstream of an ATG start codon that ensures efficient tranlation initiation. A SalI site (GTCGAC) immediately upstream of the ATG start codon (GTCGACATG) is an effective Kozak sequence Minicircle: Covalently closed circular plasmid derivatives in which the bacterial region has been removed from the parent plasmid by in vivo or in vitro intramolecular (cis-) site specific recombination or in vitro restriction digestion/ligation mSEAP: Murine secreted alkaline phosphatase Nanoplasmid vector: Vector combining an RNA selection marker with a R6K or ColE2 related replication origin. For example, NTC9385C, NTC9685C, NTC9385R, NTC9685R, NTC9385R-BE, NTC9385Ra-O1 and NTC9385Ra-O2 vectors described herein and modifications thereof NTC7382 promoter: A chimeric promoter comprising the CMV enhancer-CMV promoter-HTLV R-synthetic rabbit β globin 3′ intron acceptor-exon 2-SRF protein binding site-kozak sequence, with or without an upstream SV40 enhancer. The creation and application of this chimeric promoter is disclosed in Williams J A Supra, 2008 and included herein by reference NTC8385: NTC8385 and NTC8685 plasmids are antibiotic-free vectors that contain a short RNA (RNA-OUT) selection marker in place of the antibiotic resistance marker (kanR). The creation and application of these RNA-OUT based antibiotic-free vectors are disclosed in Williams, J A Supra, 2008 and included herein by reference NTC8685: NTC8685 (FIG. 1) is an antibiotic-free vector that contains a short RNA (RNA-OUT) selection marker in place of the antibiotic resistance marker (kanR). The creation and application of NTC8685 is disclosed in Williams, J A 2010 US Patent Application 20100184158 and included herein by reference OL1: Lambda repressor binding site in the P_(L) promoter (FIG. 7). Repressor binding to OL1 is altered by mutations in OL1, such as OL1-G (FIG. 7; this is a single base deletion that also reduces the distance between the P_(L) promoter-35 and -10 boxes from optimal 17 bp to 16 bp) and OL1-G to T (FIG. 7; this is a G to T substitution that maintains the distance between the P_(L) promoter-35 and -10 boxes at the optimal 17 bp; this is the V2 mutation described by Bailone A and Galibert F, 1980. Nucleic Acids Research 8:2147) OD₆₀₀: optical density at 600 nm PAS: Primosomal assembly site. Priming of DNA synthesis on a single stranded DNA ssi site. ØX174 type PAS: DNA hairpin sequence that bindspriA, which, in turn, recruits the remaining proteins to form the preprimosome [priB, dnaT, recruits dnaB (delivered by dnaC)], which then also recruits primase (dnaG), which then, finally, makes a short RNA substrate for DNA polymerase I. ABC type PAS: DNA hairpin binds dnaA, recruits dnaB (delivered by dnaC) which then also recruits primase (dnaG), which then, finally, makes a short RNA substrate for DNA polymerase I. See Masai et al, 1990 J Biol Chem 265:15134. For example, the R6K plasmid CpG free ssiA primosomal assembly site (SEQ ID NO:21) or alternative ØX174 type or ABC type primosomal assembly sites, such as those disclosed in Nomura et al Supra, 1991 PAS-BH: Primosomal assembly site on the heavy (leading) strand PAS-BH region: pBR322 origin region between ROP and PAS-BL (approximately pBR322 2067-2351) PAS-BL: Primosomal assembly site on the light (lagging) strand PBS: Phosphate buffered Saline

PCR: Polymerase Chain Reaction

pDNA: Plasmid DNA pINT pR pL vector: The pINT pR pL integration expression vector is disclosed in Luke et al 2011 Mol Biotechnol 47:43 and included herein by reference. The target gene to be expressed is cloned downstream of the pL1 promoter (FIG. 7). The vector encodes the temperature inducible cI857 repressor, allowing heat inducible target gene expression. P_(L) promoter: Lambda promoter left (FIG. 7). P_(L) is a strong promoter that is repressed by the cI repressor binding to OL1, OL2 and OL3 repressor binding sites. The temperature sensitive cI857 repressor allows control of gene expression by heat induction since at 30° C. the cI857 repressor is functional and it represses gene expression, but at 37-42° C. the repressor is inactivated so expression of the gene ensues Plasmid: An extra chromosomal DNA molecule separate from the chromosomal DNA which is capable of replicating independently from the chromosomal DNA pMB1 RNAI: pMB1 plasmid origin encoded RNAI that represses RNAII regulated targets (SEQ ID NO: 31; SEQ ID NO:32) that represses RNAII regulated targets such as those described in Grabherr R, Pfaffenzeller I. 2006 US patent application US20060063232 and Cranenburgh R M. 2009; U.S. Pat. No. 7,611,883 P_(min): Minimal 678 bp pUC replication origin SEQ ID NO:42 and functional variants with base substitutions and/or base deletions. Vectors described herein incorporating P_(min) include NTC8385-Min and NTC8885MP-U6

Pol: Polymerase

polyA: Polyadenylation signal or site. Polyadenylation is the addition of a poly(A) tail to an RNA molecule. The polyadenylation signal is the sequence motif recognized by the RNA cleavage complex. Most human polyadenylation sites contain an AAUAAA motif and conserved sequences 5′ and 3′ to it. Commonly utilized polyA sites are derived from the rabbit β globin (NTC8685; FIG. 1), bovine growth hormone (gWIZ; pVAX1), SV40 early, or SV40 late polyA signals pUC replication origin: pBR322-derived replication origin, with G to A transition that increases copy number at elevated temperature and deletion of the ROP negative regulator pUC plasmid: Plasmid containing the pUC origin R6K plasmid: NTC9385R, NTC9685R, NTC9385Ra-O1 and RNA9385Ra-O2 vectors disclosed herein, as well as modifications, and alternative R6K vectors known in the art including but not limited to pCOR vectors (Gencell), pCpGfree vectors (Invivogen), and CpG free University of Oxford vectors including pGM169 R6K replication origin: a region which is specifically recognized by the plasmid-specified Rep protein to initiate DNA replication. Includes but not limited to R6K replication origin sequence disclosed as SEQ ID NO:1: R6K Origin, and CpG free versions (SEQ ID NO:22) as disclosed in Drocourt et al U.S. Pat. No. 7,244,609 and incorporated herein by reference R6K replication origin-RNA-OUT bacterial region: Contains a R6K replication origin for propagation and the RNA-OUT selection marker

Rep: Replication

Rep protein dependent plasmid: A plasmid in which replication is dependent on a replication (Rep) protein provided in Trans. For example, R6K replication origin, ColE2-P9 replication origin and ColE2 related replication origin plasmids in which the Rep protein is expressed from the host strain genome. Numerous additional Rep protein dependent plasmids are known in the art, many of which are summarized in del Solar et al 1998 Microbiol. Mol. Biol. Rev 62:434-464 which is included herein by reference RNA-IN: Insertion sequence 10 (IS10) encoded RNA-IN, an RNA complementary and antisense to RNA-OUT. When RNA-IN is cloned in the untranslated leader of a mRNA, annealing of RNA-IN to RNA-OUT reduces translation of the gene encoded downstream of RNA-IN RNA-IN regulated selection marker: A genomically expressed RNA-IN regulated selectable marker. In the presence of plasmid borne RNA-OUT, expression of a protein encoded downstream of RNA-IN is repressed. An RNA-IN regulated selection marker is configured such that RNA-IN regulates either 1) a protein that is lethal or toxic to said cell per se or by generating a toxic substance (e.g. SacB), or 2) a repressor protein that is lethal or toxic to said bacterial cell by repressing the transcription of a gene that is essential for growth of said cell (e.g. murA essential gene regulated by RNA-IN tetR repressor gene). For example, genomically expressed RNA-IN-SacB cell lines for RNA-OUT plasmid propagation are disclosed in Williams, J A Supra, 2008 (SEQ ID NO:23) and included herein by reference. Alternative selection markers described in the art may be substituted for SacB RNA-OUT: Insertion sequence 10 (IS10) encoded RNA-OUT (SEQ ID NO:24), an antisense RNA that hybridizes to, and reduces translation of, the transposon gene expressed downstream of RNA-IN. The sequence of the core RNA-OUT sequence (SEQ ID NO:24) and complementary RNA-IN SacB genomically expressed RNA-IN-SacB cell lines can be modified to incorporate alternative functional RNA-IN/RNA-OUT binding pairs such as those disclosed in Mutalik et al. 2012 Nat Chem Biol 8:447, including, but not limited to, the RNA-OUT A08/RNA-IN S49 pair, the RNA-OUT A08/RNA-IN S08 pair, and CpG free modifications of RNA-OUT A08 that modify the CG in the RNA-OUT 5′ TTCGCT sequence to a non-CpG sequence RNA-OUT Selectable marker: An RNA-OUT selectable marker DNA fragment including E. coli transcription promoter and terminator sequences flanking an RNA-OUT RNA. An RNA-OUT selectable marker, utilizing the RNA-OUT promoter and terminator sequences, that is flanked by DraIII and KpnI restriction enzyme sites, and designer genomically expressed RNA-IN-SacB cell lines for RNA-OUT plasmid propagation, are disclosed in Williams, J A Supra, 2008 (SEQ ID NO:23) and included herein by reference. The RNA-OUT promoter and terminator sequences flanking the RNA-OUT RNA may be replaced with heterologous promoter and terminator sequences. For example, the RNA-OUT promoter may be substituted with a CpG free promoter known in the art, for example the I-EC2K promoter or the P5/6 5/6 or P5/6 6/6 promoters disclosed in Williams, J A Supra, 2008 and included herein by reference RNA selectable marker: also RNA selection marker. An RNA selectable marker is a plasmid borne expressed non translated RNA that regulates a chromosomally expressed target gene to afford selection. This may be a plasmid borne nonsense suppressing tRNA that regulates a nonsense suppressible selectable chromosomal target as described by Crouzet J and Soubrier F 2005 U.S. Pat. No. 6,977,174 included herein by reference. This may also be a plasmid borne antisense repressor RNA, a non limiting list included herein by reference includes RNA-OUT that represses RNA-IN regulated targets, pMB1 plasmid origin encoded RNAI that represses RNAII regulated targets (SEQ ID NO: 31; SEQ ID NO:32; Grabherr and, Pfaffenzeller Supra. 2006; Cranenburgh R M. Supra, 2009), IncB plasmid pMU720 origin encoded RNAI that represses RNA II regulated targets (SEQ ID NO: 33; SEQ ID NO:34; Wilson et al Supra, 1997), ParB locus Sok of plasmid R1 that represses Hok regulated targets, Flm locus FlmB of F plasmid that represses fhnA regulated targets (Morsey Mass., 1999 U.S. Pat. No. 5,922,583). An RNA selectable marker may be another natural antisense repressor RNAs known in the art such as those described in Wagner EGH, Altuvia S, Romby P. 2002. Adv Genet 46:361 and Franch T, and Gerdes K. 2000. Current Opin Microbiol 3:159. An RNA selectable marker may also be an engineered repressor RNAs such as synthetic small RNAs expressed SgrS, MicC or MicF scaffolds as described in Na D, Yoo S M, Chung H, Park H, Park J H, Lee S Y. 2013. Nat Biotechnol 31:170 ROP: Repressor of primer sacB: Structural gene encoding Bacillus subtilis levansucrase. Expression of sacB in gram negative bacteria is toxic in the presence of sucrose SEAP: Secreted alkaline phosphatase shRNA: Short hairpin RNA SR: Spacer region. As used herein, spacer region is the region linking the 5′ and 3′ ends of the eukaryotic region sequences. The eukaryotic region 5′ and 3′ ends are typically separated by the replication origin and selection marker. In simple single RNA Pol II transcription vectors this will be between the RNA Pol II promoter region (5′ to a promoter, enhancer, boundary element, S/MAR) and the RNA Pol II polyA region (3′ to a polyA sequence, eukaryotic transcriptional terminator sequence, boundary element, S/MAR). For example, in NTC9385R (FIG. 5) the spacer region is region between NheI site at 1663 and KpnI site at 460. In dual RNA Pol H transcription vectors, the eukaryotic sequences separated by the spacer will depend on the orientation of the two transcription elements. For example, with divergent or convergent RNA Pol II transcription units, the spacer region may separate two polyA sequences or two enhancers respectively. In RNA Pol II, RNA Pol III dual expression vectors, the spacer region may separate an RNA Pol H enhancer and a RNA Pol III promoter. The spacer region may encode bacterial or eukaryotic selectable markers, bacterial transcription terminators, eukaryotic transcription terminators, boundary elements, S/MARs, RNA Pol I or RNA Pol III expressed sequences or other functionalities ssi: Single stranded initiation sequences SV40 enhancer: Region containing the 72 bp and optionally the 21 bp repeats target antigen: Immunogenic protein or peptide epitope, or combination of proteins and epitopes, against which an immune response can be mounted. Target antigens may by derived from a pathogen for infectious disease applications, or derived from a host organism for applications such as cancer, allergy, or autoimmune diseases. Target antigens are well defined in the art. Some examples are disclosed in Williams, Supra, 2008 and are included herein by reference TE buffer: A solution containing approximately 10 mM Tris pH 8 and 1 mM EDTA Transcription terminator: Bacterial: A DNA sequence that marks the end of a gene or operon for transcription. This may be an intrinsic transcription terminator or a Rho-dependent transcriptional terminator. For an intrinsic terminator, such as the trpA terminator, a hairpin structure forms within the transcript that disrupts the mRNA-DNA-RNA polymerase ternary complex. Alternatively, Rho-dependent transcriptional terminators require Rho factor, an RNA helicase protein complex, to disrupt the nascent mRNA-DNA-RNA polymerase ternary complex. Eukaryotic: PolyA sites are not ‘terminators’, instead internal cleavage at PolyA sites leaves an uncapped 5′end on the 3′UTR RNA for nuclease digestion. Nuclease catches up to RNA Pol II and causes termination. Termination can be promoted within a short region of the poly A site by introduction of RNA Pol H pause sites (eukaryotic transcription terminator). Pausing of RNA Pol H allows the nuclease introduced into the 3′ UTR mRNA after PolyA cleavage to catch up to RNA Pol II at the pause site. A nonlimiting list of eukaryotic transcription terminators know in the art include the C2×4 terminator (Ashfield R, Patel A J, Bossone S A, Brown H, Campbell R D, Marcu K B, Proudfoot N.J. 1994. EMBO J 13:5656) and the gastrin terminator (Sato K, Ito R, Baek K H, Agarwal K, 1986. Mol. Cell. Biol. 6:1032). Terminator element may stabilize mRNA by enhancing proper 3′-end processing of mRNA (Kim D, Kim J D, Baek K, Yoon Y, Yoon J. 2003. Biotechnol Prog 19:1620) Transgene: Target antigen or protein or RNA gene that is cloned into a vector ts: Temperature sensitive μg: microgram μl: microliter UTR: Untranslated region of a mRNA (5′ or 3′ to the coding region) VARNA: Adenoviral virus associated RNA, including VARNAI (VAI or VA1) and or VARNAII (VAII or VA2) from any Adenovirus serotype, for example, serotype 2, serotype 5 or hybrids thereof VARNAI: Adenoviral virus associated RNAI, also referred to as VAI, or VA1, from any Adenovirus serotype, for example, serotype 2, serotype 5 or hybrids thereof Vector: A gene delivery vehicle, including viral (e.g. alphavirus, poxvirus, lentivirus, retrovirus, adenovirus, adenovirus related virus, etc) and nonviral (e.g. plasmid, midge, transcriptionally active PCR fragment, minicircles, bacteriophage, etc) vectors. These are well known in the art and are included herein by reference Vector backbone: Eukaryotic region and bacterial region of a vector, without the transgene or target antigen coding region

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The invention relates generally to plasmid DNA compositions and methods to improve plasmid expression and plasmid production. The invention can be practiced to improve expression of vectors such as eukaryotic expression plasmids useful for gene therapy, genetic immunization and or interferon therapy. The invention can be practiced to improve the copy number of vectors such as eukaryotic expression plasmids useful for gene therapy, genetic immunization and or interferon therapy. It is to be understood that all references cited herein are incorporated by reference in their entirety.

According to one preferred embodiment, the present invention provides for method of increasing in vivo expression of transgene from covalently closed super-coiled plasmid DNA, which comprises modifying the plasmid DNA to replace the pMB1, ColE1 or pBR322 derived replication origin and selectable marker with a replication origin selected from the group consisting of an P_(min) minimal pUC replication origin, ColE2-P9 replication origin, ColE2 related replication origin, and R6K replication origin and a RNA selectable marker; transforming the modified plasmid DNA into a Rep protein producing bacterial cell line rendered competent for transformation; and isolating the resultant transformed bacterial cells. The modified plasmid produced from these cells has increased transgene expression in the target organism.

In one preferred embodiment, the spacer region encoded pMB1, ColE1 or pBR322 derived replication origin is replaced with a CpG free ColE2 origin. In another preferred embodiment, a primosome assembly site is incorporated into a ColE2 plasmid DNA backbone to improve plasmid copy number. In yet another preferred embodiment, the pMB1, ColE1 or pBR322 derived replication origin is replaced with a CpG free R6K origin.

The methods of plasmid modification of the present invention have been surprisingly found to improve plasmid expression in the target organism. Increased expression vectors may find application to improve the magnitude of DNA vaccination mediated antigen reactive B or T cell responses for preventative or therapeutic vaccination, increase RNA and or protein transgene levels to improve gene replacement therapy or gene knockdown therapy, increase plasmid based expression levels of DNA vector expressed therapeutic antibodies that neutralize infectious diseases such as influenza, HIV, malaria, hepatitis C virus, tuberculosis, etc.

Plasmid encoded transgene expression in the target organism is preferably increased by employing specific constructs or compositions incorporated in a vector. According to one preferred embodiment, the present invention provides a composition for construction of a vector, comprising a ColE2 origin with at least 90% sequence identity to the sequences set forth as SEQ ID NO: 4, SEQ ID NO: 5, SEQ ID NO: 6, SEQ ID NO: 7, and a RNA selectable marker and a eukaryotic region, wherein the ColE2 origin is operably linked to the RNA selectable marker and eukaryotic region. It has been surprisingly found that this ColE2 origin-RNA selectable marker improves plasmid encoded transgene expression in the target organism. According to another preferred embodiment, the resultant vector of the invention has at least 95% sequence identity to a sequence selected from the group consisting of: SEQ ID NO: 8, SEQ ID NO: 9.

According to another preferred embodiment, the present invention provides a composition for construction of a vector, comprising an R6K origin with at least 90% sequence identity to the sequences set forth as SEQ ID NO: 1, SEQ ID NO: 22, and a RNA selectable marker and a eukaryotic region, wherein the R6K origin is operably linked to the RNA selectable marker and eukaryotic region. It has been surprisingly found that this R6K origin-RNA selectable marker improves plasmid encoded transgene expression in the target organism. According to another preferred embodiment, the resultant vector of the invention has at least 95% sequence identity to a sequence selected from the group consisting of: SEQ ID NO: 2, SEQ ID NO: 3, SEQ ID NO: 39, SEQ ID NO: 40, SEQ ID NO: 41.

As used herein, the term “sequence identity” refers to the degree of identity between any given query sequence, e.g., SEQ ID NO: 2, and a subject sequence. A subject sequence may, for example, have at least 90 percent, at least 95 percent, or at least 99 percent sequence identity to a given query sequence. To determine percent sequence identity, a query sequence (e.g., a nucleic acid sequence) is aligned to one or more subject sequences using any suitable sequence alignment program that is well known in the art, for instance, the computer program ClustalW (version 1.83, default parameters), which allows alignments of nucleic acid sequences to be carried out across their entire length (global alignment). Chema et al., 2003 Nucleic Acids Res., 31:3497-500. In a preferred method, the sequence alignment program (e.g., ClustalW) calculates the best match between a query and one or more subject sequences, and aligns them so that identities, similarities, and differences can be determined. Gaps of one or more nucleotides can be inserted into a query sequence, a subject sequence, or both, to maximize sequence alignments. For fast pair-wise alignments of nucleic acid sequences, suitable default parameters can be selected that are appropriate for the particular alignment program. The output is a sequence alignment that reflects the relationship between sequences. To further determine percent identity of a subject nucleic acid sequence to a query sequence, the sequences are aligned using the alignment program, the number of identical matches in the alignment is divided by the length of the query sequence, and the result is multiplied by 100. It is noted that the percent identity value can be rounded to the nearest tenth. For example, 78.11, 78.12, 78.13, and 78.14 are rounded down to 78.1, while 78.15, 78.16, 78.17, 78.18, and 78.19 are rounded up to 78.2.

According to another preferred embodiment, the present invention provides methods and compositions for production of a Rep protein dependent plasmid vector. Production cell lines providing improved heat inducible P_(L) promoter expression of a Rep protein integrated into the genome and expressed from the heat inducible P_(L) promoter incorporating the OL1-G deletion (SEQ ID NO: 11), or the heat inducible P_(L) promoter incorporating the OL1-G to T substitution (SEQ ID NO: 12). It has been surprisingly found that these promoter modifications improves Rep protein dependent plasmid vector copy number in shake flask and fermentation cultures.

Turning now to the drawings, FIG. 1. shows an annotated map of the antibiotic free NTC8685 pUC origin expression vector with the locations of the pUC origin, PAS-BH primosomal assembly site, SV40 enhancer and other key elements indicated. The replication origin (PAS-BH and pUC origin) is from the AgeI (230) site to the DraIII (1548) site (1318 bp total). The antibiotic free RNA-OUT selection marker is between the DraIII (1548) and KpnI (1695) sites (147 bp total). The spacer region encoded bacterial region (replication and selection) of this vector is 1465 bp.

FIG. 2 shows an annotated map of the antibiotic-free NTC9685C ColE2 origin expression vector with the locations of the primosomal assembly site, ColE2 Replication origin (Replication origin) and other key elements indicated. The spacer region encoded bacterial region (replication and selection) of this vector is 281 bp [NheI site-ssiA-ColE2 Origin (+7)-RNA-OUT-KpnI site] (SEQ ID NO:20).

FIG. 3 shows an annotated map of the antibiotic-free NTC9685R R6K origin expression vector with the locations of the primosomal assembly site, R6K Replication origin (R6K mini-origin) and other key elements indicated. The spacer region encoded bacterial region (replication and selection) of this vector is 466 bp [NheI site-trpA terminator-R6K Origin-RNA-OUT-KpnI site] (SEQ ID NO:19).

FIG. 4 shows an annotated map of the antibiotic-free NTC9385C ColE2 origin expression vector with the locations of the primosomal assembly site, ColE2 Replication origin (Replication origin) and other key elements indicated. The spacer region encoded bacterial region (replication and selection) of this vector is 281 bp [NheI site-ssiA-ColE2 Origin (+7)-RNA-OUT-KpnI site] (SEQ ID NO:20). This vector differs from NTC9685C in that the VA1 RNA and SV40 enhancer are not present.

FIG. 5 shows an annotated map of the antibiotic-free NTC9385R R6K origin expression vector with the locations of the primosomal assembly site, R6K Replication origin (R6K mini-origin) and other key elements indicated. The spacer region encoded bacterial region (replication and selection) of this vector is 466 bp [NheI site-trpA terminator-R6K Origin-RNA-OUT-KpnI site] (SEQ ID NO:19). This vector differs from NTC9685R in that the VA1 RNA and SV40 enhancer are not present.

FIG. 6 shows an annotated map of the pINT pR pL R6K Rep pi P42L-P106L-F107S (P3-) integration vector; key features such as the cI857 ts repressor, P_(L) promoter, R6K Rep protein, HK022 phage attachment site for site specific integration into the E. coli genome, R6K replication origin and spectinomycin/streptomycin resistance marker (SpecR StrepR) are shown.

FIG. 7 show an annotated sequence of the P_(L) promoter with locations of the P_(L) promoter OL1, OL2 and OL3 repressor binding sites, −10 and −35 promoter elements for P_(L)1 and P_(L)2 promoters. The OL1 mutations OL1-G and OL1-G to T alterations are shown.

FIG. 8 shows an annotated map of the pINT pR pL ColE2 Rep protein integration vector; key features such as the cI857 ts repressor, P_(L) promoter, ColE2 Rep protein, HK022 phage attachment site for site specific integration into the E. coli genome, R6K replication origin and spectinomycin/streptomycin resistance marker (SpecR StrepR) are shown.

FIG. 9 shows Nanoplasmid expression in vitro after lipofectamine transfection of HEK293 cell line of various EGFP transgene encoding vectors.

FIG. 10 shows Nanoplasmid expression in vivo after intramuscular injection with EP of various muSEAP transgene encoding vectors.

FIG. 11 shows a ColE2 origin Nanoplasmid shRNA expression vector. In this vector, a 22 bp shRNA is expressed from the RNA Polymerase III H1 promoter, with a TTTTTT terminator. The bacterial region is the NTC9385C and NTC9685C Bacterial region (SEQ ID NO:20).

FIG. 12 shows an IncB RNAI based RNA selection marker. A) Genomically expressed target of IncB RNAI RNA selection marker (SEQ ID NO: 35). Plasmid expressed RNAI binding to the pseudoknot in the complementary genomically expressed RNAII target prevents translation of the downstream SacB gene, conferring sucrose resistance. The RNAI-10 and -35 promoter elements are mutated to prevent RNAI expression. B) Structure of plasmid expressed IncB RNAI RNA selection marker (SEQ ID NO: 34) encoding the IncB RNAI antisense repressor (SEQ ID NO: 33).

The invention also relates to compositions and methods for producing high expression level plasmids. The present invention provides sequences that, when introduced into a vector backbone, increase plasmid expression.

The surprising observation that a ColE2 replication origin-RNA selection marker or R6K replication origin-RNA selection marker can be utilized as a plasmid expression enhancer is disclosed.

As described herein, plasmid expression is increased by replacement of the pMB1, ColE1 or pBR322 derived origin-selection marker bacterial region with an R6K origin-RNA selection marker in the plasmid backbone. In yet another preferred embodiment, the R6K origin is CpG free. In yet another preferred embodiment, the R6K origin is included with an RNA-OUT selection marker. In yet another preferred embodiment, the R6K origin is included with an pMB1 RNAI selection marker. In yet another preferred embodiment, the R6K origin is included with an IncB RNAI selection marker.

In yet another preferred embodiment, plasmid expression is increased by replacement of the pMB1, ColE1 or pBR322 derived origin-selection marker bacterial region with a ColE2 origin-RNA selection marker in the plasmid backbone. In yet another preferred embodiment, the ColE2 origin is CpG free. In yet another preferred embodiment, the ColE2 origin is included with an RNA-OUT selection marker. In yet another preferred embodiment, the ColE2 origin is included with an pMB1 RNAI selection marker. In yet another preferred embodiment, the ColE2 origin is included with an IncB RNAI selection marker. In yet another preferred embodiment, the ColE2 origin is included with a primosome assembly site.

In yet another preferred embodiment, plasmid expression is increased by replacement of the pMB1, ColE1 or pBR322 derived origin-selection marker with a P_(min) minimal pUC, ColE2 or a R6K origin in the plasmid backbone spacer region and an RNA selection marker in an intron. In yet another preferred embodiment, the R6K or ColE2 origin is CpG free. In yet another preferred embodiment, the RNA selection marker is the RNA-OUT selection marker. In yet another preferred embodiment, the RNA selection marker is the pMB1 RNAI selection marker. In yet another preferred embodiment, the RNA selection marker is the IncB RNAI selection marker.

EXAMPLES

The methods of the invention are further illustrated by the following examples. These are provided by way of illustration and are not intended in any way to limit the scope of the invention.

Example 1 Heat Inducible R6K Replication Origin Plasmid Production

Fermentation: Fermentations were performed using proprietary fed-batch media (NTC3019, HyperGRO media) in New Brunswick BioFlo 110 bioreactors as described (Carnes and Williams, Supra, 2011). The seed cultures were started from glycerol stocks or colonies and streaked onto LB medium agar plates containing 6% sucrose. The plates were grown at 30-32° C.; cells were resuspended in media, and used to provide approximately 0.1% inoculums for the fermentations that contained 0.5% sucrose to select for RNA-OUT plasmids.

Antibiotic-free RNA-OUT plasmid fermentations were performed in E. coli strain XL1Blue [recA1 endA1 gyrA96 thi-1 hsdR17 supE44 relA1 lac [F′proAB lacIqZΔM15 Tn10 (Tet^(r))] (Stratagene, La Jolla, Calif.)] or GT115 [F-mcrA Δ(mrr-hsdRMS-mcrBC) φ80lacZΔM15 ΔlacX74 recA1 rspL (StrA) endA1 Δdcm uidA(ΔMluI)::pir-116 ΔsbcC-sbcD (Invivogen, San Diego)] strains containing chromosomally integrated pCAH63-CAT RNA-IN-SacB (P5/6 6/6) at the phage lambda integration site as disclosed in Williams, J A Supra, 2008. SacB (Bacillus subtilis levansucrase) is a counterselectable marker which is lethal to E. coli cells in the presence of sucrose. Translation of SacB from the RNA-1N-SacB transcript is inhibited by plasmid encoded RNA-OUT. This facilitates plasmid selection in the presence of sucrose, by inhibition of SacB mediated lethality.

Analytical Methods: Culture samples were taken at key points and at regular intervals during all fermentations. Samples were analyzed immediately for biomass (OD₆₀₀) and for plasmid yield. Plasmid yield was determined by quantification of plasmid obtained from Qiagen Spin Miniprep Kit preparations as described (Carnes and Williams, Supra, 2011). Briefly, cells were alkaline lysed, clarified, plasmid was column purified, and eluted prior to quantification. Agarose gel electrophoresis analysis (AGE) was performed on 0.8-1% Tris/acetate/EDTA (TAE) gels as described in Carnes and Williams J A, Supra, 2011.

R6K background: The R6K gamma plasmid replication origin requires a single plasmid replication protein n that binds as a monomer to multiple repeated ‘iteron’ sites (seven core repeats containing TGAGNG consensus) and as a dimer to repressive sites [TGAGNG (dimer repress) as well as to iterons with reduced affinity]. Various host factors are used including IHF, DnaA, and primosomal assembly proteins DnaB, DnaC, DnaG (Abhyankar et al 2003 J Biol Chem 278:45476-45484). The R6K core origin contains binding sites for DnaA and IHF that affect plasmid replication (π, IHF and DnaA interact to initiate replication).

Different versions of the R6K gamma replication origin have been utilized in various eukaryotic expression vectors, for example pCOR vectors (Soubrier et al 1999, Gene Therapy 6:1482) and a CpG free version in pCpGfree vectors (Invivogen, San Diego Calif.), and pGM169 (University of Oxford). Incorporation of the R6K replication origin does not improve expression levels compared to an optimized pUC origin vector (Soubrier et al Supra, 1999). However, use of a conditional replication origin such as R6K gamma that requires a specialized cell line for propagation adds a safety margin since the vector will not replicate if transferred to a patients endogenous flora.

A highly minimalized R6K gamma derived replication origin that contains core sequences required for replication (including the DnaA box and stb 1-3 sites; Wu et al, 1995. J Bacteriol. 177: 6338-6345), but with the upstream π dimer repressor binding sites and downstream π promoter deleted (by removing one copy of the iterons, as with pCpG; see map below) was designed (SEQ ID NO:1) and NTC9685R and NTC9385R expression vectors incorporating it constructed (see Example 3).

Typical R6K production strains incorporate the n protein derivative PIR116 that contains a P106L substitution that increases copy number (by reducing π dimerization; π monomers activate while π dimers repress). Fermentation results with pCOR (Soubrier et al., Supra, 1999) and pCpG plasmids (Hebel H L, Cai Y, Davies L A, Hyde S C, Pringle I A, Gill D R. 2008. Mol Ther 16: 5110) were low, around 100 mg/L in PIR116 cell lines.

As expected, fermentation yields of the R6K expression vector NTC9685R-EGFP in R6K plasmid production cell line NTC641642 (GT115-SacB; GT115 modified for RNA-OUT AF vector selection by insertion of pCAH63-CAT RNA-IN-SacB (P5/6 6/6) into the genome. The GT115 genome encoded endogenous π gene P3 promoter constitutively expresses R6K replication protein π containing the pir-116 mutation; Metcalf et al, 1994; Gene 138; 1-7) were low (Table 1). Mutagenesis of the pir-116 replication protein and selection for increased copy number has been used to make new production strains. For example, the TEX2pir42 strain contains a combination of P106L and P42L. The P42L mutation interferes with DNA looping replication repression. The TEX2pir42 cell line improved copy number and fermentation yields with pCOR plasmids with reported yields of 205 mg/L (Soubrier F. 2004. World Patent Application WO2004033664). Methods to improve R6K origin yields are needed.

Other combinations of π copy number mutants have been shown to improve copy number. This includes ‘P42L and P113S’ and ‘P42L, P106L and F107S’ (Abhyankar et al 2004. J Biol Chem 279:6711-6719).

Two cell lines using the endogenous π gene P3 promoter to express π mutants ‘P42L and P113S’ (SEQ ID NO:13) (NTC640722 cell line) and ‘P42L, P106L and F107S’ (SEQ ID NO:14) were constructed and tested for copy number improvement with NTC9685R-EGFP. Two additional cell lines using the P_(L) promoter in addition to the endogenous π gene P3 promoter to express π mutants ‘P42 L and P113S’ (NTC641981 cell line) and ‘P42L, P106L and F107S’ (NTC641053 cell line) were made and tested for copy number improvement with NTC9685R-EGFP. R6K production cell lines were made in XL1-Blue SacB (XL1-Blue attλ:P5/6 6/6-RNAIN-SacB, CmR).

These cell lines were constructed as follows. The R6K replication proteins 17 were cloned into the pINT pR pL integration vectors as described in Luke et at Supra, 2011 and included herein by reference. Constructed R6K Rep protein vectors were integrated into the genome at the HK022 phage attachment site as described in Luke et al, Supra, 2011. Briefly the pINT pINT pR pL R6K Rep vectors were amplified by PCR to delete the R6K replication origin, ligated to form a circle, and integrated into the HK022 attachment site using the pAH69 helper plasmid as described.

The results (Table 1) demonstrated that constitutive expression of ‘P42 L and P113S’ or ‘P42L, P106L and F107S’ resulted in much higher levels of NTC9685R-EGFP than the NTC641642 encoded P106L Rep protein. However, constitutive expression from P3 resulted in low overall biomass and plasmid multimerization with P42L, P106L and F107S (RF306, RF314), due to high plasmid levels and resultant metabolic burden during the growth phase.

TABLE 1 2.6 kb NTC9685R-EGFP R6K Nanoplasmid fermentation yields in R6K rep cell lines Growth Induced Final phase Growth phase Induced plasmid Plasmid Ferm temp spec temp spec Final yield multimer- # Cell line Rep Gene Promoter (C.) yield^(a) (C.) yield^(a) OD₆₀₀ (mg/L) ization RF310 NTC641642 P106L Const P3 37 1.1 NA, 37 1.2 43 53 RF323 NTC641642 P106L Const P3 37 ND NA, 37 0.9 54 49 Monomer RF305 NTC640722 P42L-P113S Const P3 30 3.4 37 3.6 96 345 Monomer RF321 NTC641981 P42L-P113S pR PL & P3 32 4.4-5.0 42 2.8 93 259 Monomer^(b) RF306 NTC641053 P42L-P106L- pR PL & P3 30 3.1 37 6.6 86 567 Multimer F107S RF314 NTC641053 P42L-P106L- pR PL & P3 32 2.6-4.7 42 7.1 79 558 Multimer F107S RF351 NTC661135 P42L-P106L- pR PL only 32 0.4 42 1.45 88 128 Monomer F107S RF326 NTC66113 P42L-P106L- pR PL OL1 32 0.64 42 6.7 81 545 Monomer 5-MUT F107S G RF358 NTC711055 P42L-P106L- pR PL OL1 32 1 42 5.9 118 690 Monomer F107S G RF359 NTC711231 P42L-P106L- pR PL OL1 30 1.8 42 8.5 82 695 Monomer F107S G to T NTC640721 = NTC5402-P42L-P106L-F107S ND = Not determined NTC5402 = XL1Blue, SacB NTC640722 = NTC5402-P42L-P113S NA = Not applicable NTC54208 = XL1Blue, SacB, dcm- NTC641053 = NTC5402-pR pL P42L-P106L-F107S NTC641642 = GT115-SacB (relA+) pir116 = P106L ^(a)Specific Yield = mg plasmid/L/OD600 NTC641981 = NTC5402-pR pL P42L-P113S ^(b)Some dimer present NTC661135 = NTC54208-pR pL P42L-P106L-F107S (P3-) NTC661135-MUT = NTG54208-pR pL (OL1-G) P42L-P106L-F107S (P3-) NTC661134 = NTC5402-pR pL P42L-P113S (P3-) NTC711055 = NTC54208-pR pL (OL1-G) P42L-P106L-F107S (P3-) NTC711231 = NTC54208-pR pL (OL1-G to T) P42L-P106L-F107S (P3-)

Heat inducible versions were then made by deletion of the P3 promoter to determine if P_(L) promoter mediated replication protein induction in a temperature shift improved R6K plasmid production yields and quality by reduction of plasmid copy number and metabolic burden during the reduced temperature growth phase. A strain encoding a deletion of the P3 promoter expressing P42L, P106L and F107S (NTC661135, incorporating a single copy of the pINT pR pL R6K Rep pi P42L-P106L-F107S (P3-) integration vector; FIG. 6, SEQ ID NO:17) constructed as described above dramatically reduced copy number during the reduced temperature growth phase with copy number induction after temperature upshift (Table 1; RF351). However, the yield (128 mg/L) was overall lower than with the P3 promoter (567, 558 mg/L).

However, excellent results were obtained after fermentation with a second NTC661135 cell line (RF326) in which plasmid copy number was increased 10 fold by temperature shifting, resulting in excellent fmal plasmid yields of 545 mg/L. PCR amplification and sequencing of the P42L, P106L and F107S expression cassette from the RF326 cell line (NTC661135-MUT) and the RF351 cell line (NTC661135) demonstrated that NTC661135-MUT contained a mutation in the OL1 lambda repressor binding site in the P_(L) promoter (FIG. 7; OL1-G this is a single base deletion that also reduces the distance between the P_(L)1 promoter-35 and -10 boxes from optimal 17 bp to 16 bp).

This mutation was introduced into the pINT pR pL R6K Rep pi P42L-P106L-F107S (P3-) integration vector by PCR mutagenesis and a sequence verified clone incorporating the OL1-G mutation integrated into the genome (NTC711055) as described above. Fermentation evaluation of this cell line with the NTC9685R-EGFP plasmid (Table 1; RF358) demonstrated similar dramatic 6 fold heat inducible plasmid copy number induction, resulting in excellent final plasmid yields of 690 mg/L.

Repressor binding to OL1 is altered by mutations in OL1, such as OL1-G (FIG. 7; SEQ ID NO:11) and V2 (OL1-G to T; FIG. 7; SEQ ID NO:12; this is a G to T substitution that maintains the distance between the P_(L) promoter-35 and -10 boxes at the optimal 17 bp; this is the V2 mutation described by Bailone and Galibert, Supra, 1980).

The OL1-G to T (V2) mutation was introduced into the pINT pR pL R6K Rep pi P42L-P106L-F107S (P3-) integration vector by PCR mutagenesis and a sequence verified clone incorporating the OL1-G mutation integrated into the genome as described above to create NTC711231. Fermentation evaluation of this cell line with the NTC9685R-EGFP plasmid (Table 1; RF359) demonstrated, similar to OL1G, a dramatic 5 fold heat inducible plasmid copy number induction, resulting in excellent final plasmid yields of 695 mg/L.

Cell lines incorporating the pINT pR pL R6K Rep pi P42L-P106L-F107S (P3-) integration vector containing either the wildtype P_(L) promoter (NTC66I 135, SEQ ID NO:10), the OL1-G mutation (NTC711055, SEQ ID NO:11) or the OL1-G to T mutation (NTC711231, SEQ ID NO:12) were transformed with the NTC9385R-EGFP plasmid and yields in shake flask determined (Table 2). The results demonstrated the OL1-G and OL1-G to T mutations dramatically improve temperature inducible R6K plasmid yields in shake flask culture. Improved yield with two different R6K plasmids (NTC9385R, Table 2; NTC9685R, Table 1) in either LB shake flask media or HyperGRO fermentation media demonstrates improved temperature inducible R6K plasmid is generic, and is not plasmid or growth media specific. Thus the invention can be utilized with a plurality of R6K origin vectors, in various plasmid growth media described in the art and various temperature induction profiles.

Likewise the pINT pR pL R6K Rep plasmids can be integrated into alternative E. coli strains to create production hosts. Any strain that is acceptable for plasmid production, such as JM108, BL21, DH5, DH1, DH5α, GT115, GT116, DH10B, EC100, can be converted to a high yield temperature inducible R6K plasmid production host by integration of a pINT pR pL R6K Rep plasmid into the genome. The pR pL R6K Rep expression cassette may alternatively be removed from the pINT vector backbone and directly integrated into the chromosome, for example, using Red Gam recombination cloning (for example, using the methods described in Datsenko and Wanner 2000 Proc Natl Acad Sci USA 97:6640-6645). The pR pL R6K Rep expression cassette may alternatively be transferred to a different vector backbone, such as integration vectors that target different phage attachment sites, for example, those described by Haldimann and Wanner 2001, J Bacteriol 183:6384-6393.

TABLE 2 NTC9385R-EGFP LB media shake flask production yields in R6K production strains 30° C. 32° C. 37° C. Rep Gene Spec Spec Spec Cell Line Rep Gene Promoter yield^(a) yield^(a) yield^(a) NTC661135 P42L-P106L- P_(R) P_(L) 1.2 2.1 0.6 F107S NTC711055 P42L-P106L- P_(R) P_(L) 0.5 1.3 9.1 F107S (OL1-G) NTC711231 P42L-P106L- P_(R) P_(L) 1.3 7.0 9.3 F107S (OL1-G to T) ^(a)Specific yield = mg plasmid/L/OD₆₀₀

These results are surprising since the art teaches that P_(L) promoter mutations in the OL1 binding site such as V2 (OL1-G to T) are constitutively active due to an inability of the lambda repressor to stop expression from the P_(L) promoter (Bailone and Galibert, Supra, 1980). While not limiting the application of the invention, it is possible that the lambda repressor is able to repress the P_(L) promoter through binding to the OL2 and OL3 sites (FIG. 7) when the P_(L) promoter is integrated in the genome; the lambda repressor may not be able to bind multiple copies of the mutated P_(L) promoter as in a phage infection.

The application of two independent OL1 mutations (OL1-G and OL1-G to T) to create cell lines for high yield R6K plasmid production demonstrates the general utility of P_(L) promoters incorporating OL1 mutations to improve heat inducible chromosomal expression of a target protein. Any OL1 mutation is contemplated for use in the current invention. New OL1 mutations can be defined by standard methods known in the art, for example error prone mutagenesis of the OL1 region, with subsequent selection of beneficial OL1 mutations by screening for heat inducible target protein production. The target protein can be a Rep protein as described herein, or a fluorescent marker, or any target protein or RNA. Thus application of P_(L) promoters incorporating OL1 mutations is contemplated generally as a platform for improved heat inducible chromosomal expression of any recombinant protein or RNA. This can be applied to improve heat inducible chromosomal expression of any recombinant protein or RNA using either shake flask (Table 2) or fermentation (Table 1) culture.

These cell lines may also be used to produce alternative R6K plasmids, such as CpGfree vectors, pCOR vectors, pGM169, etc. P_(L) promoter vectors with the OL1 mutations may be used to improve expression of alternative target proteins or mRNAs from the genome.

These cell lines may also be used to produce alternative Rep protein dependent plasmids, such as ColE2-P9 replication origin plasmids (Examples 2 and 3), ColE2 related replication origin plasmids, etc. Numerous additional Rep protein dependent plasmids known in the art may also be produced using the cell lines of the invention. Many Rep protein dependent plasmids are described in del Solar et al Supra, 1998 which is included herein by reference.

Heat inducible target protein production may be further improved, by further mutating OL1-G and OL1-G to T or an alternative OL1 mutation to incorporate a mutation in the P_(L)-10 GATACT sequence to make it more closely match the consensus TATAAT (−35 is already consensus TTGACA (FIG. 7).

Alternative temperature sensitive (ts) lambda repressors (cI) may be substituted for the cITs857 mutation utilized in the pINT vectors. Multiple alternative ts lambda repressors have been defined (for example, see Lieb M. 1979 J Virol 32:162 included herein by reference) or new ts lambda repressors may be isolated by screening for temperature sensitive cI function.

Alternative integration methods rather than the described pINT pR pL integration vectors may be utilized such as integration of the pR pL expression cassette into the genome at defined sites using Red Gam recombination cloning (for example, using the methods described in Datsenko and Wanner Supra, 2000).

Example 2 ColE2-P9 Replication Origin Plasmid Production

Similar to plasmid R6K, the ColE2 replication origin is separate from the replication protein, so the ColE2 replication origin theoretically may be utilized to construct Rep protein dependent plasmids. Here application of the ColE2 replication origin, using ColE2-P9 as an example, to produce ColE2 Rep protein dependent plasmids is demonstrated (Example 3).

ColE2 background: The ColE2 replication origin (for example, ColE2-P9) is highly conserved across the ColE2-related plasmid family (15 members are compared in Hiraga et al Supra, 1994, and 53 ColE2 related plasmid members including ColE3 are compared in Yagura et al Supra, 2006, both references are included herein by reference). Plasmids containing this origin are normally 10 copies/cell (low copy #). For application in gene therapy or DNA vaccination vectors, the copy number of ColE2 replication origin vectors needs to be improved dramatically.

Expression of the ColE2-P9 replication (Rep) protein is regulated by antisense RNA (RNAI). Copy number mutations have been identified that interfere with this regulation and raise the copy number to 40/cell (Takechi et al 1994 Mol Gen Genet 244:49-56).

pINT pR pL ColE2 Rep protein cell line NTC641711: The ColE2 Rep protein (SEQ ID NO:15) was expressed using the heat inducible pINT pR pL vector as described in Example 1. The ColE2 RNAI region was removed and replaced with an optimal kozak-ATG region. This modification deletes the RNAI-10 promoter box. The Rep internal RNAI-35 box (Yasueda et al 1994 Mol Gen Genet 244:41-48) was mutagenized (from (opposite strand) TTGAAG to CTGAAG) to lower the consensus. A high copy mutation in the Rep coding region (C139T; Nagase et al 2008 Plasmid 59:36-44) was also incorporated.

These changes do not alter the Rep protein amino acid sequence (SEQ ID NO:15).

The ColE2 Rep gene was PCR amplified from CGSC Strain #8203 with following primers

15061101: ggaacgggatccagaaggagatatacatatgagtgccgtacttcagcgcttcaggga (SEQ ID NO:26) 15061102: ggaacggaattcttatcattttgcgagatctggatcacat (SEQ ID NO:27)

The 920 bp PCR product was digested with BamHI/EcoRI and cloned into BamHI/EcoRI digested pINT pR pL BamHI/EcoRI (3766, polylinker). Recombinant clones were selected by restriction digestion and sequence verified. The map of the resultant pINT pR pL CoE2 Rep integration vector is shown in FIG. 8. The integration plasmid was integrated into NTC54208 (XL1Blue-sacB [dcm-]) to create cell line NTC641711 as described in Example 1.

A kanR ColE2-P9 replication origin fluorescent reporter plasmid (pDNAVACCUltra5-C2-P5/6,4/6-T7RBS EGFP) was constructed to select for copy number improving mutations. The 1067 bp pUC replication origin was removed from the kanR pDNAVACCUltra5-P5/6,4/6-T7RBS EGFP vector (the pDNAVACCUltra5-EGFP vector disclosed in Williams J A, 2006 World patent application WO06078979, modified to express the EGFP reporter in E. coli utilizing the weak constitutive P5/6,4/6 promoter disclosed in Lissemore J L, Jankowski J T, Thomas C B, Mascotti D P, deHaseth P L. 2000. Biotechniques 28: 82-89 and included herein by reference) by NheI-DraIII digestion, and replaced with a 132 bp ColE2-P9 replication origin (+7-ssiA; see below). Recombinant clones were recovered in cell line NTC641711 and the ColE2 origin confirmed by restriction digestion and sequence verification. This demonstrates that the ColE2-P9 Rep protein cell line NTC641711 can be used to select and propagate ColE2 replication origin containing plasmids.

ColE2 Rep Protein Mutagenesis, Selection of Copy Number Increasing Mutants

Background: The ColE2 Rep protein binds as a monomer to the ColE2 replication origin. However, Rep protein exists mostly as a dimer in solution; Rep dimerization will limit the amount of active monomeric Rep which is hypothesized will maintain ColE2 plasmid at a low copy number (Han M, Aoki K, Yagura M, Itoh T. 2007. Biochem Biophys Res Commun 353:306). Copy number autoregulation by Rep protein dimerization is a common copy number control mechanism. Significantly, R6K Rep protein mutations such as P106L (PIR116) utilized in Example 1 that interfere with dimer formation dramatically increase copy number (Abhyankar et al Supra, 2004). It was hypothesized that ColE2 plasmid copy number can also be increased with a dimerization deficient Rep mutation.

Mutagenesis: ColE2 Rep protein functional domains have been mapped and a region responsible for dimerization defined (FIG. 8). The dimerization region was mutagenized using the GeneMorph H Random Mutagenesis Kit (Stratagene) as described (Lanza A M, Alper H S. 2011. Methods in Molecular Biology, Vol. 765, Strain Engineering: Methods and Protocols, Ed. J. A. Williams, Humana Press Inc., Totowa, N.J. pp 253-274). The Rep gene was error prone PCR amplified from the pINT pR pL ColE2 Rep vector with the kit enzyme. The mutagenized dimerization domain (359 bp BstB1/EcoRI fragment; FIG. 8) was cloned back into the pINT pR pL ColE2 Rep vector replacing the non mutagenized 359 bp BstB1/EcoRI fragment. An integrated pINT pR pL ColE2 Rep library was then made by mass genome integration without purification of the mutagenized plasmid pool into NTC54208 containing the pAH69 integration plasmid. The integrated Rep library was transformed with the kanR pDNAVACCUltra5-C2-P5/6,4/6-T7RBS EGFP fluorescent ColE2 reporter plasmid and transformants plated on LB+kanamycin agar plates and grown at 37° C. This EGFP reporter plasmid allows 1) visual selection of plasmid copy number improvement using a Dark Reader for agar plate illumination; and 2) quantitative copy number evaluation (fluorescence is linear with copy number) in liquid culture using a fluorometer (BioTek FLx800 microplate fluorescence reader). Two colonies were isolated from 30,000 screened cells with significantly higher colony fluorescence. Both cell lines were verified to have improved pDNAVACCUltra5-C2-P5/6,4/6-T7RBS EGFP plasmid copy number in liquid culture demonstrating increased fluorescence corresponds to increased copy number.

The lambda repressor—P_(L)—ColE2 Rep regions from genomic DNA from these two cell lines were amplified by PCR and sequenced to determine the basis for improvement. One colony had a mutation in the lambda repressor which presumably reduces the activity of the repressor leading to Rep protein overexpression. This demonstrates that alternations to the vector backbone that increase P_(L) promoter activity improve ColE2 plasmid copy number. Thus ColE2 copy number, like R6K plasmids, will be improved by making a cell line with the ColE2 Rep protein (or Rep protein copy number improving mutations) expressed from pINT pR pL vectors incorporating the lambda repressor binding site OL1 mutations (OL1-G and OL1-G to T) identified in Example 1.

The second colony had a mutation in the Rep protein (G194D; SEQ ID NO:16). This mutation was introduced back into the pINT pR pL ColE2 Rep vector to create the pINT pR pL ColE2 Rep protein mutant (G194D) (SEQ ID NO:18). The integration plasmid was integrated into NTC54208 (XL1Blue-sacB [dcm-]) to create cell line NTC701131 as described in Example 1. ColE2 plasmid production yields were improved in the ColE2 Rep protein mutant cell line NTC701131, compared to the parental ColE2 Rep protein cell line NTC641711 in both shake flask and fermentation culture (Table 3). This demonstrates that the ColE2 Rep protein, like the R6K Rep protein, can be mutagenized to create copy number improving variants.

Combining the ColE2 Rep protein G194D mutant with pINT pR pL vector incorporating the lambda repressor binding site OL1 OL1-G to T mutation identified in Example 1 further increased copy number (cell line NTC710351=NTC54208-pR pL (OL1-G to T) ColE2 rep G194D) and fermentation production yields (Example 3).

TABLE 3 NTC9385C-Luc plasmid performance in different processes and production cell lines^(a) ColE2 Plasmid LB shake flask (37 C.) Plasmid + Shake flask (37 C.) ^(c) HyperGRO fermentation production Spec Spec Spec cell line OD₆₀₀ mg/L yield ^(b) OD₆₀₀ mg/L yield ^(b) OD₆₀₀ mg/L yield ^(b) NTC641711 3.4 1.4 0.4 13.0 12.3 0.93 148 61 0.4 NTC701131 3.4 3.1 0.9 16.6 17.9 1.1 113 110 1.0 Rep mutant 140 142 1.0 ^(a)All plasmid preparations at harvest were high quality monomer. ^(b) Specific yield = mg plasmid/L/OD₆₀₀ ^(c) Plasmid + media from Thomson Instruments Company

Additional rounds of mutagenesis of the wild type Rep protein, or mutagenesis of mutant Rep protein such as G194D may be performed to further improve copy number. The entire Rep protein or subfragments can be mutagenized (e.g. BamH1-EcoRI fragment for entire Rep protein; FIG. 8). The ideal mutant will be similar to the R6K Rep protein mutants ‘P42 L and P113S’ and ‘P42L, P106L and F107S’ (Example 1) with higher copy number at 37-42° C. (i.e. higher levels of replication inducing monomeric Rep protein are produced from the heat inducible P_(R) P_(L) promoters) to facilitate adaptation into NTC's inducible fermentation plasmid production process as in Example 1.

ColE2 origin vectors: The following vectors containing the minimal ColE2-P9 origin (Yagura and Itoh 2006 Biochem Biophys Res Commun 345:872-877) and various origin region modifications were constructed.

+7-ssiA: This combines the ColE2 origin (+7) (SEQ ID NO:4) with ssiA from plasmid R6K (SEQ ID NO:21). Thus ssiA vectors contain, in addition to the ColE2-P9 origin, a downstream primosome assembly site. Like most plasmid origins, the ColE2 origin contains a primosomal assembly site about 100 bp downstream of the origin (Nomura et al Supra, 1991). This site primes lagging strand DNA replication (Masai et al 1990 JBiol Chem 265:15124-15133) which may improve plasmid copy number or plasmid quality. The ColE2 PAS (ssiA) is similar to PAS-BH (ColE1 ssiA=PAS-BL Marians et al 1982 JBiol Chem 257:5656-5662) and both sites (and PAS-BH) are CpG rich ØX174 type PAS. A CpG free PAS (ssiA from R6K; Nomura et al Supra, 1991; SEQ ID NO:21) that acts as a dnaA, dnaB dnaC (ABC) primosome on a dnaA box hairpin sequence (Masai et al 1990 J Biol Chem 265:15134-15144) was selected for inclusion in the +7-ssiA vectors. Alternative ABC or ØX174 type PAS sequences are functionally equivalent to ssiA from R6K, and may be substituted for ssiA in these ColE2 replication origin vectors.

+7-ssiA vectors were constructed by replacing the pUC origin NheI-DraIII region (FIG. 1) with a NheI-DraIII compatible synthetic ssiA-+7 ColE2 origin restriction fragment (FIG. 2, FIG. 4). Plasmids were transformed into ColE2 plasmid production NTC641711. The correct ColE2 vectors were identified by restriction digestion and sequence verified.

+7 (no ssiA): This deletes the ssiA sequence from +7-ssiA while retaining the ColE2 origin (+7) (SEQ ID NO:4). The ssiA sequence was removed by NheI-MfeI digestion, the sites blunted with Klenow and the vector religated to delete the 64 bp ssiA region. Plasmids were transformed into ColE2 plasmid production host NTC641711. The correct ColE2 vector was identified by restriction digestion and sequence verified.

+7 CpG-ssiA: This combines the ColE2 replication origin (+7 CpG) (SEQ ID NO:5) with ssiA from plasmid R6K (SEQ ID NO:21). The single CpG in the ColE2 replication origin (Table 4) was removed from the vector by site directed mutagenesis. Plasmids were transformed into ColE2 plasmid production host NTC641711. The correct ColE2 vector was identified by restriction digestion and sequence verified.

+16-ssiA: This combines the ColE2 replication origin (+16) (SEQ ID NO:7) with ssiA from plasmid R6K (SEQ ID NO:21). A 16 bp region of homology downstream of the ColE2-P9 replication origin is conserved with the ColE3 replication origin. This 16 bp region was added to the vector by site directed mutagenesis. Plasmids were transformed into ColE2 plasmid production host NTC641711. The correct ColE2 vector was identified by restriction digestion and sequence verified.

Min-ssiA: This combines the ColE2 Min replication origin (SEQ ID NO:6) with ssiA from plasmid R6K (SEQ ID NO:21). This is the minimal 32 bp ColE2 sequence sufficient for replication defined by Yasueda et al 1989 Mol Gen Genet 215:209) (SEQ ID NO:28), extended by an additional 6 bp (Table 4). This vector was created by site directed mutagenesis of the +7-ssiA clone. Plasmids were transformed into ColE2 plasmid production host NTC641711. The correct ColE2 vector was identified by restriction digestion and sequence verified.

The series of plasmids were transformed into ColE2 plasmid production host NTC701131 (Rep mutant). The resultant cell lines were then used determine plasmid copy number and quality (Table 4). Two different backbones were evaluated with the +7-ssiA and +16-ssiA ColE2 replication origins to determine the effect of plasmid sequence alterations.

The results demonstrate that the four replication origin variants containing the ssiA sequence [+7-ssiA; +16-ssiA; +7 (CpG free) ssiA; Min-ssiA] are functional in NTC701131, replicating to a similar copy number (0.73-1×). All plasmids were high quality monomer. This demonstrates that any of these minimal ColE2 origin variants can function as a plasmid replication origin to produce high quality plasmid.

Yagura et al Supra, 2006 have demonstrated that the Min ColE2 Replication origin (SEQ ID NO:28, which is reverse complement of residues 7-38, in FIG. 1 of Yagura et al Supra, 2006) can be further deleted without eliminating replication function. Yagura et al, Supra, 2006, demonstrated that the core sequence is residues 8-35, with residues 5-36 are required for full activity. The +7 ColE2 Replication origin (SEQ ID NO:4; which is the reverse complement of residues 0-44 in FIG. 1 of Yagura et al Supra, 2006) could therefore be reduced to span residues 8-35 or 5-36 of FIG. 1 of Yagura et al Supra, 2006. Such vectors should replicate similarly to the disclosed vectors. As well, a number of base changes can be made within the core ColE2 origin 8-34 region that do not affect ColE2 replication (see changes to residues that retain function in Table 2 in Yagura et al Supra, 2006).

A surprising observation that is contrary to the teachings of Yagura et al Supra, 2006 is that the +7(CpG free)-ssiA ColE2 origin is fully functional. This origin contains a change of a G to C in residue 36 (FIG. 1 Yagura et al Supra, 2006). This change is predicted to reduce origin activity (Relative transformation frequency 5 fold reduced with 36 G-C to C-G; Table 2 in Yagura et al Supra, 2006). This may be due to the different context in the +7(CpG free)-ssiA ColE2 origin, or the longer origin fragment (0-44). Regardless, the 121 bp +7(CpG free)-ssiA ColE2 origin (SEQ ID NO 29) or +7(CpG free) ColE2 origin (SEQ ID NO 5) are smaller CpG free replication origin alternatives to the 260 bp CpG free R6K replication origins (SEQ ID NO:22). CpG free ColE2 origins may be utilized to construct CpG free plasmid vectors, or to retrofit the replication origin in existing vectors with a CpG free alternative replication origin. Combinations of a CpG free ColE2 or R6K replication origin with a CpG free RNA-OUT selection marker may be utilized to construct antibiotic free CpG free plasmid vectors, or to retrofit the selection marker-replication origin region in existing vectors with an antibiotic free-CpG free alternative selection marker-replication origin.

The ssiA sequence was not necessary for plasmid replication, although removal of ssiA in +7 (no ssiA) reduced copy number to 55% of +7 (ssiA). Thus inclusion of a primosomal assembly site is beneficial to ColE2 plasmid copy number.

TABLE 4 Co1E2 Origin EGFP vector production in NTC701131 Co1E2 production cell line ^(b) Specific Yield  Relative copy Origin ^(c) Cell line ID# OD600 mg/L (mg/L/OD600) number ^(a) +7-ssiA 071-020-2D 13.5 20.7 2.3 1x (NTC9385C) 11.4 20.4 1.8 12.5 27.2 2.2 (2.1 avg) +16-ssiA 071-029-1A 19.6 23.5 1.2 0.70x 16.5 20.9 1.3 13.1 24.8 1.9 (1.5 avg) +7(CpG free)-  071-020-3D 10.5 25.1 2.4 0.83x ssiA 8.4 11.6 1.4 10.1 14.1 1.4 (1.7 avg) Min-ssiA 071-020-4D 11.3 13.7 1.2 0.73x 15.9 37.2 2.3 13.3 14.8 1.1 (1.5 avg) +7(no ssiA) 071-020-5D 12.8 17.2 1.3 0.55x 13.5 16.4 1.2 13.5 14.5 1.1 (1.2 avg) +7-ssiA 071-020-6D 14.7 22.3 1.5 0.70x (NTC9685C) 13.2 21.3 1.6 11.7 14.9 1.3 (1.5 avg) +16-ssiA 071-020-7D 13.5 26.9 1.9 0.76x (VA1-SV40) 11.9 17.7 1.5 13.2 18.8 1.4 (1.6 avg) ^(a) Average specific yield/+7-ssiA average specific yield (specific yield = mg plasmid/L/OD₆₀₀) ^(b) Plasmid+ media, 37° C. throughout growth conditions. All plasmid preparations at harvest were high quality monomer ^(c) NTC Co1E2 origin sequences +7: caaaag gg cgctgttatctgataaggcttatctggtctcatttt g (SEQ ID NO: 4) Min bold underlined +7(CpG free): caaaag ggGgctgttatctgataag gcttatctgg tctcattttg (SEQ ID NO: 5)(C to G change in bold underlined core to eliminate CpG is uppercase double underlined) Min: The 32 bp minimal origin defined by Yasueda et al Supra, 1989 (SEQ ID NO: 28) is Bold underlined): ggc g ct g ttatctgataagg c ttatctg g tct catttt (SEQ ID NO: 6) +16: CTGCTCAAAAAGACGCcaaaag g g cgct g ttatctgataag g cttatctggtctcattttg (SEQ ID NO: 7) Min bold underlined, additional 16 by in +16 is uppercase

Example 3 NTC9382C, NTC9385C, NTC9382R, NTC9385R, NTC9682C, NTC9685C, NTC9682R, and NTC9685R Vectors

A series of AF eukaryotic expression vectors incorporating these novel ColE2-P9 derived vector origins were made. To replace the pUC origin, the +7 (ssiA) ColE2 origin from Example 2 was selected as well as the R6K origin (SEQ ID NO:1) from Example 1. The features of these vectors (NTC9382C, NTC9385C, NTC9382R, NTC9385R, NTC9682C, NTC9685C, NTC9682R, and NTC9685R) are summarized in Table 5.

NTC9682C, NTC9685C (FIG. 2), NTC9682R, NTC9685R (FIG. 3) are antibiotic-free RNA-OUT ColE2 origin (C) or R6K origin (R) versions of the pUC origin NTC8682, NTC8685 (FIG. 1) equivalents disclosed in Williams J A, Supra, 2010. These vectors contain the SV40 enhancer upstream of the CMV enhancer, and Adenoviral serotype 5 VA RNAI regulatory RNA (VARNAI).

NTC9382C, NTC9385C (FIG. 4), NTC9382R, NTC9385R (FIG. 5) are versions without the SV40 enhancer or VARNAI sequences.

NTC9682C, NTC9682R, NTC9382C, and NTC9382R all express the secreted transgene product as TPA fusion proteins while NTC9685C, NTC9685R, NTC9385C, and NTC9385R all express the native transgene product from a vector encoded ATG start codon.

The remainder of the vector sequences is identical between the different vectors, with the exception that the two R vectors NTC9682R and NTC9382R (FIG. 3, FIG. 5) contain the trpA bacterial terminator, which is absent in the two C vectors NTC9682C and NTC9382C (FIG. 2, FIG. 4).

An R6K gamma origin vector was constructed by swapping in the R6K gamma origin (SEQ ID NO:1) in a NotI-DraIII R6K origin synthetic gene for the corresponding NotI-DraIII pUC origin region in NTC8685. The NTC9682R, NTC9685R NTC9382R, NTC9385R vectors were made by standard restriction digestion mediated fragment swaps. The ColE2 origin vectors were constructed in a similar fashion, by swapping in the +7 ssiA ColE2 origin in a NheI-DraIII synthetic gene for the corresponding NheI-DraIII pUC origin region. The NTC9682C, NTC9685C, NTC9382C, NTC9385C vectors were made by standard restriction digestion mediated fragment swaps. The 466 bp Bacterial region [NheI site-trpA terminator-R6K Origin-RNA-OUT-KpnI site] for NTC9385R and NTC9685R is shown in SEQ ID NO:19. The 281 bp Bacterial region [NheI site-ssiA-ColE2 Origin (+7)-RNA-OUT-KpnI site] for NTC9385C and NTC9685C is shown in SEQ ID NO:20.

High fermentation yields in HyperGRO media are obtained with these vectors. For example 695 mg/mL with NTC9685R-EGFP in R6K production cell line NTC711231 (Table 1) and 672 mg/L with NTC9385C-EGFP in ColE2 production cell line NTC710351.

These are just a few possible nonlimiting vector configurations. Many alternative vector configurations incorporating the novel R6K or ColE2 origin vector modifications may also be made, including but not limited to vectors with alternative selection markers, alternative promoters, alternative terminators, and different orientations of the various vector-encoded elements or alternative R6K or ColE2 origins as described in Examples 1 and 2.

TABLE 5 NTC9382C, NTC9385C, NTC9382R, NTC9385R, NTC9682C, NTC9685C, NTC9682R, and NTC9685R vectors VA RNAI SV40 Transgene Vector Origin present enhancer targeting NTC9382C ColE2-P9 No No Secretion (TPA) NTC9382R R6K No No Secretion (TPA) NTC9682C ColE2-P9 Yes Yes Secretion (TPA) NTC9682R R6K Yes Yes Secretion (TPA) NTC9385C ColE2-P9 No No Native (SEQ ID NO: 8) NTC9385R R6K No No Native (SEQ ID NO: 2) NTC9685C ColE2-P9 Yes Yes Native (SEQ ID NO: 9) NTC9685R R6K Yes Yes Native (SEQ ID NO: 3)

An example strategy for cloning into these vectors is outlined below.

GTCGAC ATG--------Gene of interest----Stop  SalI                                                codon------AGATCT          BglII

For the NTC9385C, NTC9685C, NTC9385R, and NTC9685R vectors, the ATG start codon (double underlined) is immediately preceded by a unique SalI site. The SalI site is an effective Kozak sequence for translational initiation. In NTC9382C, NTC9682C, NTC9382R, and NTC9682R, the SalI site is downstream in frame with the optimized TPA secretion sequence (SEQ ID NO:25). The TPA ATG start codon is double underlined and the SalI site single underlined. SEQ ID NO:25: TPA secretion sequence atggatgcaatgaagagagggctctgctgtgtgctgctgctgtgtggagcagtettcgtttcgcccageggtaccggatccgtcgac

For precise cloning, genes are copied by PCR amplification from clones, cDNA, or genomic DNA using primers with SalI (5′ end) and BglII (3′ end) sites. Alternatively, genes are synthesized chemically to be compatible with the unique SalI/BglII cloning sites in these vectors.

For NTC9385C, NTC9685C, NTC9385R, and NTC9685R, the start codon ATG may immediately follow the SalI site (GTCGACATG) since the SalI site is a high function Kozak sequence. For all vectors one or two stop codons (preferably TAA or TGA) may be included after the open reading frame, prior to the BglII site. A PCR product or synthetic gene designed for NTC9385C, NTC9685C, NTC9385R, and NTC9685R is compatible with, and can also be cloned into, the NTC9382C, NTC9682C, NTC9382R, and NTC9682R vectors.

EGFP and muSEAP transgene versions NTC9385C, NTC9685C, NTC9385R, and NTC9685R were constructed by standard restriction fragment swaps. The muSEAP gene is secreted using its endogenous secretion signal, while EGFP is cell associated. Expression levels in vitro were determined using EGFP, while expression levels in vivo were determined using muSEAP. Expression levels were compared to the NTC8685 parent vector, the gWIZ vector, and a minicircle comparator.

Adherent HEK293 (human embryonic kidney), A549 (human lung carcinoma), cell lines were obtained from the American Type Culture Collection (Manassas, Va., USA). Cell lines were propagated in Dulbecco's modified Eagle's medium/F12 containing 10% fetal bovine serum and split (0.25% trypsin-EDTA) using Invitrogen (Carlsbad, Calif., USA) reagents and conventional methodologies. For transfections, cells were plated on 24-well tissue culture dishes. plasmids were transfected into cell lines using Lipofectamine 2000 following the manufacturer's instructions (Invitrogen).

Total cellular lysates for EGFP determination were prepared by resuspending cells in cell lysis buffer (BD Biosciences Pharmingen, San Diego, Calif., USA), lysing cells by incubating for 30 min at 37° C., followed by a freeze-thaw cycle at −80° C. Lysed cells were clarified by centrifugation and the supernatants assayed for EGFP by FLX800 microplate fluorescence reader (Bio-Tek, Winooski, Vt., USA). The results are summarized in FIG. 9 and Table 6.

Groups of five mice were injected with plasmid DNA in an IACUC-approved study. Five micrograms of muSEAP plasmid in 25 or 50 μL of phosphate-buffered saline (PBS) was injected intramuscularly (IM) into a tibialis cranialis muscles of female BALB/c mice or ND4 Swiss Webster mice (6 to 8 weeks old) followed by Ichor TriGrid electroporation. SEAP levels in serum were determined using the Phospha-light SEAP Reporter Gene Assay System from Applied Biosystems (Foster City, Cali.) according to the manufacturer's instructions. The results are summarized in FIG. 10 and Table 6.

The NTC9385C, NTC9685C, NTC9385R, and NTC9685R vectors had similar expression to the parent NTC8685 vector in vitro, and higher expression than the gWIZ comparator (FIG. 9). Thus substitution of the R6K or ColE2 replication origin for the pUC origin was not detrimental for eukaryotic cell expression. However, surprisingly, in vivo expression was dramatically improved compared to NTC8685 or gWIZ with the ColE2 and R6K origin vectors (FIG. 10). For example the NTC9385C vector was unexpectedly improved 1.5 to 3.8× that of NTC8385 (Table 6) or NTC8685 (not shown) after IM delivery with EP.

TABLE 6 gWIZ and NTC9385C Nanoplasmid expression compared to NTC8685 % NTC8685 % NTC8685 % NTC8685 % NTC8685 % NTC8685 expression expression expression expression expression T = 7 days T = 7 days T = 28 days T = 28 days Plasmid in vitro ^(a) BALB/c ^(b) ND4 ^(b) BALB/c ^(b) ND4 ^(b) gWIZ 58 59 57 21 57 NTC8385 NA NA 101 NA 101 NTC9385C 92 377  349 150  233 Minicircle ^(c) NA 89 NA 40 NA ^(a) 100 ng/well EGFP transgene vectors transfected with lipofectamine into HEK293 cells ^(b) murine SEAP (muSEAP) transgene vectors in 8-10 week old BALB/c or ND4 Swiss Webster female mice, 5 μg dose with EP intramuscular into one anterior tibialis muscle followed by Ichor TriGrid electroporation. 25 μL dose for ND4 mice, 50 μL dose for BALB/c. ^(c) Minicircle equivalent to NTC9385C or NTC9385R, with NheI-KpnI region containing the replication origin and RNA-OUT selection marker (bacterial region) removed from NTC8385-muSEAP by SpeI/NheI digestion, gel purification of the eukaryotic region, in vitro ligation and supercoiling with DNA gyrase. The SpeI site is the same site used to truncate the CMV promoter to make NTC8685 and the NTC9385C-muSEAP vector so the minicircle eukaryotic region is the same as NTC9385C-muSEAP, the difference being the C2 and RNA-OUT region including the KpnI site is deleted in the minicircle. NA = Not assayed

This improved in vivo expression was not specific to the CMV promoter. Versions of

NTC8685-muSEAP and NTC9385C-muSEAP were constructed in which the murine creatine kinase (MCK) promoter (3 copies of the MCK Enhancer upstream of the MCK promoter and 50 bp of the MCK exon 1 leader sequence; Wang B, Li J, Fu F H, Chen C, Zhu X, Zhou L, Jiang X, Xiao X. 2008. Gene Ther 15:1489) was substituted for the CMV promoter. The swaps replaced the entire CMV enhancer CMV promoter-exon 1 leader (NTC8685: from a XbaI site immediately after the SV40 enhancer to a SacII site in the CMV derived exon 1 leader sequence FIG. 1; NTC9385C: from the KpnI site to a SacII site in the CMV derived exon 1 leader sequence FIG. 4) with the MCK enhancer, MCK promoter-exon 1 leader retaining the HTLV-I R portion of exon 1. Purified plasmid DNA from the resultant vectors, NTC8685-MCK-muSEAP (4847 bp) and NTC9385C-MCK-muSEAP (3203 bp), was injected IM into one anterior tibialis muscle of 8-10 week old BALB/c female mice (5 mice/group), 5 μg dose in 50 μL, followed by Ichor TriGrid electroporation as described in Table 6. SEAP levels in serum was determined on day 28 (T=28) post delivery. The NTC9385C-MCK-muSEAP vector (98.4±55.8) had 4.5× higher average expression than NTC8685-muSEAP (22.0±10.9). All 5 NTC9385C-MCK-muSEAP injected mice had higher muSEAP levels than any of the NTC8685-muSEAP mice. This demonstrates that improved in vivo expression with the Nanoplasmid vectors of the invention is not specific to the CMV promoter.

While the basis for expression improvement is unknown, it is not simply due to the size difference between the parent pUC origin vectors and the modified R6K origin-RNA selection marker or ColE2 origin-RNA selection marker vectors of the invention, since expression was not improved with a minicircle comparator vector that contains no bacterial region (Table 6). This demonstrates improved in vivo expression with the R6K origin-RNA selection marker or ColE2 origin-RNA selection marker vectors is not the result of simple elimination of a threshold amount of bacterial region sequences.

Reduction of the vector spacer region size as described herein by replacement of the spacer region replication origin and selection marker with the R6K, ColE2 origin-RNA selection marker vectors of the invention will also increase the duration of in vivo expression since expression duration is improved with plasmid vectors in which the bacterial region is removed (minicircle) or replaced with a spacer region of up to at least 500 bp (Lu J, Zhang F, Xu S, Fire A Z, Kay M A. 2012. Mol Ther. 20:2111-9). Thus the replicative minicircle vectors of the invention also have additional utility for applications requiring extended duration expression, such as: liver gene therapy using hydrodynamic delivery with transgenes such as α-1 antitrypsin (AAT) for AAT deficiency, Coagulation Factor VIII for Hemophilia A Therapy or Coagulation Factor IX for Hemophilia B Therapy etc: lung gene therapy with transgenes such as Cystic fibrosis transmembrane conductance regulator (CFTR) for cystic fibrosis etc; muscle gene therapy with transgenes such as the GNE gene for Hereditary inclusion body myopathies (HIBM), or dystrophin or dystrophin minigenes for duchenne muscular dystrophy (DMD).

Example 4 Spacer Region and Intron Modified Nanoplasmid Vectors

NTC8685 (SR=1465 bp) has much lower expression than NTC9385R (SR=466 bp) and NTC9385C (SR=281 bp). A minimal pUC origin vector was constructed with an 866 bp spacer region (NTC8385-Min; contains P_(min) minimal pUC origin-RNA-OUT). These vectors were tested for expression in vitro (lipofectamine 2000 delivery) and in vivo after intradermal electroporation delivery. As with Intramuscular injection (Example 3), the results (Table 7) demonstrated ColE2 and R6K origin vector dramatically improved in vivo expression after intradermal delivery compared to NTC8685. For example the NTC9385C vector was unexpectedly improved 2.7 to 3.1× compared to NTC8685 while the NTC9385R vector was unexpectedly improved 5.3 to 6.3× that of NTC8685 (Table 7). The 866 bp minimal pUC origin vector also improved expression to 1.4-1.9× that of NTC8685. This demonstrates improved in vivo expression with the NTC9385C and NTC9385R vectors is not limited to muscle tissue, and is observed also after intradermal delivery. Inclusion of the C2×4 eukaryotic transcription terminator in the NTC9385C vector further improved in vivo expression to 2.9 to 4.1× compared to NTC8685. This demonstrates improved in vivo expression with Nanoplasmid vectors may be obtained with alternative/additional sequences flanking the bacterial region.

A NTC9385R derivative was made in which the RNA-OUT antibiotic free marker was transferred to the intron (NTC9385Ra-02 SEQ ID NO:39; RNA-OUT SEQ ID NO:23) inserted into the unique HpaI site in the intron (SEQ ID NO: 30). This vector encodes the R6K replication origin in the spacer region (SR=306 bp). To determine splicing accuracy NTC9385Ra-02-EGFP was transfected into the A549 cell line and cytoplasmic RNA isolated. The RNA was reverse transcribed using an EGFP specific primer, and PCR amplified using Exon 1 and Exon 2 specific primers. The resultant PCR product (a single band) was determined by sequencing to be the correct spliced exon1-exon2 fragment. This demonstrated that intronic RNA-OUT is accurately removed by splicing and does not interfere with splicing accuracy. NTC9385Ra-02-EGFP also demonstrated improved in vivo expression compared to NTC8685 (Table 7: 1.6-3.5×). This demonstrates that Nanoplasmid vectors with improved expression of the current invention may encode the RNA selection marker in the intron rather than the spacer region.

The improved expression level after intradermal delivery demonstrates the application of Nanoplasmid vectors of the invention for cutaneous gene therapy applications, for example, for wound healing, burns, diabetic foot ulcer, or critical limb ischemia therapies using growth factors such as hypoxia inducible factor, hypoxia inducible factor 1α, keratinocyte growth factor, vascular endothelial growth factor (VEGF), fibroblast growth factor-1 (FGF-1, or acidic FGF), FGF-2 (also known as basic FGF), FGF-4, placental growth factor (PlGF), angiotensin-1 (Ang-1), hepatic growth factor (HGF), Developmentally Regulated Endothelial Locus (Del-1), stromal cell derived factor-1 (SDF-1), etc.

TABLE 7 SR vector expression in vitro and in vivo ID + EP ^(c) ID + EP ^(c) ID + EP ^(c) muSEAP A549 HEK-293 (pg/mL) (pg/mL) (pg/mL) Vector ^(b) SR ^(a) SR(bp) Intron ^(a) (A₄₀₅) ^(d) (A₄₀₅) ^(d) T = 4 T = 7 T = 14 NTC8685 T-VA1- 1465 HR- β 0.240 ± 3.002 ± 1.9 ± 6.7 ± 5.0 ± BH- 0.029 0.188 1.2 4.1 3.9 P-AF→ (1.0x) (1.0x) (1.0x) (1.0x) (1.0x) NTC8385- T-P_(min)- 866 HR- β 0.495 ± 2.713 ± 3.7 ± 12.4 ± 7.1 ± Min^(e) AF→ 0.027 0.177 2.7 8.1 5.2 (2.1x) (0.9x) (1.9 x) (1.9 x) (1.4 x) NTC9385R T ←R- 466 HR- β 0.604 ± 3.036 ± 12.0 ± 7.4 35.5 ±31.1 29.9± 23.4 (SEQ ID AF→ 0.04 0.169 (6.3 x) (5.3 x) (6.0 x) NO: 2) (2.5x) (1.0x) NTC9385C ←C- 281 HR- β 0.267 ± 2.720 ± 5.8 ± 20.8 ± 9.6 13.5 ±9.8 (SEQ ID AF→ 0.053 0.228 3.0 (3.1 x) (2.7x) NO: 8) (1.1x) (0.9x) (3.1 x) NTC9385C ←C- 281 HR- β 0.214 ± 2.472 ± 5.6 ± 27.7 ± 16.0 ± C2x4 AF→ 0.017 0.197 2.3 20.3 14.3 (0.89x) (0.82x) (2.9 x) (4.1 x) (3.2x) NTC9385R T ←R 306 HR- 0.524 ± 3.065 ± 3.6 ± 23.4 ± 16.5 7.8 ± a-O2 (SEQ ←AF- β 0.071 0.220 2.8 (3.5 x) 8.0 ID NO: 39) (2.2x) (1.0x) (1.9 x) (1.6 x) ^(a) Prokaryotic terminator = T; HTLV-IR = HR; B globin 3′ acceptor site = β; RNA-OUT = AF; pUC origin = P; minimal pUC origin = P_(min); R6Kγ origin = R; ColE2-P9 origin = C; C2x4 eukaryotic transcription terminator = C2x4 ^(b) All plasmids produced in XL1Blue dcm- host strains. P vectors were produced in dcm- XL1Blue NTC54208; R vectors were produced in dcm- R6K rep cell line NTC711231 (OL1 G to T); C vectors were produced in dcm- ColE2 rep cell line NTC710351 (OL1 G to T). ^(c) Dose = 50 μg in 50 μl saline injected intradermal (ID) with EP on day 0. 6 mice/group. Mean ± SD pg/mL muSEAP reported for day 4, 7 and 14. ( ) Mean muSEAP standardized to NTC8685 ^(d) muSEAP plasmid DNA transfected with Lipofectamine 2000. Mean ± SD A₄₀₅ reported 48 hrs post transfection. ( ) Mean A₄₀₅ standardized to NTC8685 ^(e)P_(min) minimal pUC origin (SEQ ID NO: 42) and RNA-OUT (bacterial region = SEQ ID NO: 43)

Example 5 RNA Pol III Nanoplasmid Vectors

An example Nanoplasmid vector for RNA Pol III directed expression of RNA is shown in FIG. 11. This vector contains the human H1 RNA Pol III promoter, but an alternative promoter such as the murine U6 promoter can be substituted. This example vector expresses a 22 bp shRNA target RNA, but alternative RNAs may be expressed, including shorter or longer shRNAs, microRNAs, aptamer RNAs, hairpin RNAs, etc. This example vector is very small, with a monomer size of 442 bp. Small size is advantageous, since vectors <1.2 kb are highly resistant to shear forces used with gene therapy delivery formulation (Catanese et al 2012. Gene Ther 19:94-100).

RNA Pol III Nanoplasmid vectors were made by standard restriction digestion mediated fragment swaps to combine either U6 or HI RNA Pol III promoter-target RNA-TTTTTT terminator (Eukaryotic region) with either the 466 bp Bacterial region [NheI site-trpA terminator-R6K Origin-RNA-OUT-KpnI site; SEQ ID NO:19] for NTC9385R-U6 and NTC9385RE-U6 vectors (Table 8) or the 281 bp Bacterial region [NheI site-ssiA-ColE2 Origin (+7)-RNA-OUT-KpnI site; SEQ ID NO:20] for NTC9385C-U6 and NTC9385CE-U6 vectors (Table 8). Versions were modified to express from the U6 promoter eRNA 18, a single stranded RNA the expression of which can be quantified by Reverse transcriptase dependent RT-PCR. Vector performance (U6 promoter mediated eRNA18 RNA expression) was determined in total RNA extracted from HEK293 at either 25 or 48 hrs after lipofectamine 2000 mediated transfection as described (Luke J, Simon G G, Soderholm J, Errett J S, August J T, Gale M Jr, Hodgson C P, Williams J A. 2011. J Virol. 85:1370). These results (Table 9) demonstrate Nanoplasmid RNA Pol III vectors direct dramatically improved RNA expression relative to a plasmid RNA Pol III vector (NTC7485-U6-eRNA18) comparator.

Random 22 bp shRNA (KP2F11) versions of NTC9385CE-U6 (903 bp NTC9385CE-U6-KP2F11 shRNA propagated in ColE2 rep cell line NTC710351) and NTC9385R-U6 (855 bp NTC9385R-U6-KP2F11 shRNA propagated in R6K rep cell line NTC711231) were fermented in HyperGRO media as described in Example 1 except fermentation and cultures for inoculations were grown at 37° C. throughout. Final yields were 149 mg/L (NTC9385CE-U6-KP2F11) and 216 mg/L (NTC9385R-U6-KP2F11 shRNA). This demonstrates that Nanoplasmid vectors for RNA Pol III expression (and RNA Pol II; Example 3) have superior manufacturing simplicity and yield compared to shRNA expressing minicircle vectors (Zhao et al 2011. Gene Ther 18:220-224). For example, optimal manufacture of minicircle vectors yields only 5 mg of minicircle per liter culture (Kay M A, He C Y, Chen Z Y. 2010. Nat Biotechnol 28:1287-1289).

TABLE 8 RNA Pol III Nanoplasmid vector expression Transfection 1: RNA isolated Transfection 2: RNA isolated 48 hr post transfection 25 hr post transfection HEK pg HEK pg RNA/ RNA/ Pol II Size 100 ng HEK 100 ng HEK Vector Enhancer (bp) mRNA^(a) Std^(b) mRNA^(a) Std^(b) NTC9385R- None NA  0.0 ± 0.0   0% EGFP (negative control) NTC8885MP- SV40  1578^(c) 62.2 ± 5.9  69% U6-eRNA18 (1.3x) NTC9385RE- SV40 1178 119.1 ± 13.9  98% U6-eRNA18 (2.5x) NTC9385R- None   945^(d) 123.7 ± 8.0   82% U6-eRNA18 (2.6x) NTC9385CE- SV40  993 119.0 ± 13.9  83% U6-eRNA18 (2.5x) NTC9385C- None   760^(e) 131.1 ± 10.5  70% 57.3 ± 2.6 127% U6-eRNA18 (2.7x) (5.0x) NTC7485- SV40 2978 48.0 ± 1.3  100% 11.5 ± 1.5 100% U6-eRNA18 (1x control) (100% (1x) (control) control) ^(a)pg eRNA18 target/100 ng total RNA isolated post-transfection. ^(b)Standardized mU6 expression compared to NTC7485-U6 shRNA eRNA18 vector (C) = test vector average pg RNA/C vector average pg RNA × test vector size (bp)/2978 × 100% ^(c)P_(min) minimal pUC origin (SEQ ID NO: 42) and RNA-OUT (bacterial region = SEQ ID NO:43) with SV40 enhancer. HI promoter version (with shRNA and no SV40) is 1035 bp ^(d)R6K origin and RNA-OUT (bacterial region = SEQ ID NO: 19). H1 promoter version (with shRNA) is 635 bp ^(e)C2 origin and RNA-OUT (bacterial region = SEQ ID NO: 20). H1 promoter version (with shRNA) is 442 bp (FIG. 11)

Example 6 Alternative RNA Selection Marker Nanoplasmid Vectors

Expression of Nanoplasmid vectors encoding RNA-OUT in the intron (both orientations of RNA-OUT SEQ ID NO:23 inserted into the unique HpaI site in the intron SEQ ID NO:30; NTC9385Ra-O1 dual and NTC9385Ra-O2 dual) demonstrated robust expression with RNA-OUT in either orientation in the intron (Table 9). Consistent with this, similarly high levels of expression are obtained with NTC9385Ra-O1 (SEQ ID NO:40) and NTC9385Ra-O2 (SEQ ID NO:39) which have opposite orientations of intronic RNA-OUT marker and the R6K origin in the spacer region. Nanoplasmid variants with the pMB1 antisense RNA RNAI (SEQ ID NO:31) with promoter and terminator region (RNAI selectable marker: SEQ ID NO:32 flanked by DraIII-KpnI restriction sites for cloning as described previously for RNA-OUT) substituted for RNA-OUT were constructed and tested for expression to determine if alternative selection markers may be utilized in place of RNA-OUT. The results (Table 9) demonstrate alternative RNA selection markers may be substituted for RNA-OUT. Substitution of RNAI for RNA-OUT in the vector backbone (NTC9385Ra-RNAI-O1) or in the intron in either orientation (NTC9385R-RNAI-O1 and NTC9385R-RNAI-O2) did not reduce expression relative to the corresponding RNA-OUT construct. To determine splicing accuracy, NTC9385R-RNAI-O1-EGFP and NTC9385R-RNAI-O2-EGFP were transfected into the A549 cell line and cytoplasmic RNA isolated from transfected HEK293 and A549 cells using the protein and RNA isolation system (PARIS kit, Ambion, Austin Tex.) and quantified by A₂₆₀. Samples were DNase treated (DNA-free DNase; Ambion, Austin Tex.) prior to reverse transcription using the Agpath-ID One step RT-PCR kit (Ambion, Austin Tex.) with a EGFP transgene specific complementary strand primer. Intron splicing was determined by PCR amplification of the reverse transcribed cytoplasmic RNA with the exon 1 and exon 2 specific primers. The resultant PCR product (a single band in each case) was determined by sequencing to be the correct spliced exon1-exon2 fragment. This demonstrated that, like intronic RNA-OUT, intronic RNAI in either orientation is accurately removed by splicing and does not interfere with splicing accuracy. This demonstrates that alternative RNA based selection markers could be substituted for RNA-OUT in the spacer region or the intron and that pMB1 RNAI is a preferred RNA based selection marker.

The RNAI transcription unit (SEQ ID NO: 32) may be substituted for the RNA-OUT selection marker (SEQ ID NO: 23) in any of the constructs described in Examples 1-6. Alternatively, the 108 bp RNAI antisense repressor RNA (SEQ ID NO: 31) may be substituted for the 70 bp RNA-OUT antisense repressor RNA (SEQ ID NO: 24) retaining the flanking RNA-OUT transcription control sequences in any of the constructs described in Examples 1-6. RNAI regulated vectors may be grown in RNAII-SacB regulated cell lines further expressing, as required, R6K, ColE2-P9, or ColE2 related rep protein. RNAII-SacB regulated cell lines may be made replacing the RNA-IN sequence in pCAH63-CAT RNA-IN-SacB (P5/6 6/6) with a RNAII target sequence as described in Williams, J A Supra, 2008 included herein by reference. Alternatively, RNAI regulated vectors may be grown in any of the RNAII regulated chromosomal selection marker cell lines disclosed in Grabherr and, Pfaffenzeller Supra. 2006; Cranenburgh Supra, 2009. These cell lines would be modified for expression, as required, of R6K, ColE2-P9, or ColE2 related rep protein.

Another preferred RNA based selection marker, IncB plasmid RNAI (SEQ ID NO:33; SEQ ID NO:34), is shown in FIG. 12. A cell line for antibiotic free sucrose selection of IncB RNAI expressing plasmid vectors is created by modification of the genomically expressed RNA-IN-SacB cell lines for RNA-OUT plasmid propagation disclosed in Williams, J A Supra, 2008 bp replacement of the 68 bp RNA-IN regulator in a PstI-MamI restriction fragment with a 362 bp PstI-MamI IncB RNAII regulator (SEQ ID NO:35). Alternatively, RNA-OUT may be substituted with one of the many RNA based selection markers know in the art.

TABLE 9 High level expression is obtained with pMB1 RNAI or RNA-OUT antisense RNA vectors A549 FU ^(b) HEK293 FU ^(b) (T = 48 hr (T = 48 hr Vector (EGFP) Spacer region ^(a) SR (bp) Intron ^(a) mean + SD) mean + SD) NTC8685 T-VA1-BH-P- 1465 HR- β ^(c)  8546 ± 1163 62068 ± 1760 AF-SV40 (1.0x)  (1.0x)  NTC8385 T-P_(min)-AF-BE 866 HR- β ^(c)  9364 ± 966 31482 ± 1822 (0.85 kb) ^(d) (1.10x) (0.51x) NTC9385C ←C -AF→ 281 HR- β ^(c)  8860 ± 382 33356 ± 1489 (SEQ ID NO: 8) (1.04x) (0.54x) NTC9385R ←R -AF→ 466 HR- β ^(c)  16237 ± 2520 55919 ± 6371 (SEQ ID NO: 2) (1.90x) (0.90x) NTC9385Ra-O2 ←R 306 HR-←AF- β 14510 ± 835 49526 ± 2179 (SEQ ID NO: 39) (1.70x) (0.80x) NTC9385Ra-O1 ←R -AF→ 466 HR-AF→- β  13929 ± 1291 56552 ± 2714 dual (1.63x) (0.91x) NTC9385Ra-O2 ←R -AF→ 466 HR-←AF- β 12543 ± 245 54379 ± 1244 dual (1.47x) (0.89x) NTC9385Ra- ←R -RNAI→ 488 HR-AF→- β 15773 ± 238 55468 ± 6619 RNAI-O1 (1.85x) (0.89x) NTC9385R- ←R -AF→ 466 HR-← RNAI - β 14296 ± 287 60630 ± 2176 RNAI-O1 (1.67x) (0.98x) NTC9385R- ←R -AF→ 466 HR-RNAI →- β 12271 ± 466 60691 ± 6482 RNAI-O2 (1.44x) (0.98x) ^(a) trpA term = T; HTLV-IR = HR; B globin 3′ acceptor site = β; RNA-OUT sucrose selection marker = AF; pUC origin RNAI antisense RNA = RNAI; pUC origin = P; R6K origin = R; ColE2 origin = C; BH = PAS-BH UP = upstream pUC plasmid derived DNA. ^(b) EGFP plasmid DNA transfected with Lipofectamine 2000. Fluorescence units (FU) reported. Mean FU standardized to NTC8685 ^(c) HR β intron is 225 bp ^(d) P_(min) minimal pUC origin (SEQ ID NO: 42) and RNA-OUT (bacterial region = SEQ ID NO: 43)

Thus, the reader will see that the improved expression vectors of the invention provide for a rational approach to improve plasmid expression.

While the above description contains many examples, these should not be construed as limitations on the scope of the invention, but rather should be viewed as an exemplification of preferred embodiments thereof. Many other variations are possible. For example, the RNA-OUT selectable marker may be substituted with an alternative RNA-OUT sequence variant that functionally binds RNA-IN to repress expression, for example, a CpG free RNA-OUT (SEQ ID NO:36). A CpG free R6K-RNA-OUT bacterial region (SEQ ID NO:37) or CpG free ColE2-RNA-OUT bacterial region (SEQ ID NO: 38) may be utilized. Likewise, the RNA-OUT promoter and/or terminator could be substituted with an alternative promoter and/or terminator. Likewise, the ColE2-P9 or R6K replication origin may be substituted with a ColE2 related replication origin, and propagated in a strain expressing the ColE2 related replication origin replication protein. Likewise, the ColE2-P9 or R6K origin may be substituted with an origin from one of the numerous additional Rep protein dependent plasmids that are know in the art, for example the Rep protein dependent plasmids described in del Solar et al Supra, 1998 which is included herein by reference. Likewise, the vectors may encode a diversity of transgenes different from the examples provided herein, for example, antigen genes for a variety of pathogens, or therapeutic genes such as hypoxia inducible factor, keratinocyte growth factor, factor IX, factor VIII, etc, or RNA genes such as microRNAs or shRNA. Likewise, the eukaryotic region may express RNA from a RNA Pol III promoter as described herein. The orientation of the various vector-encoded elements may be changed relative to each other. The vectors may optionally contain additional functionalities, such as nuclear localizing sequences, and/or immunostimulatory RNA elements as disclosed in Williams, Supra, 2008. The vectors may include a boundary element between the bacterial region and the eukaryotic region, for example, the CMV promoter boundary element upstream of the CMV enhancer (or heterologous promoter enhancer) may be included in the vector design (e.g. NTC9385R-BE; SEQ ID NO: 41). The vectors may include a eukaryotic transcriptional terminator between the bacterial region and the eukaryotic region, for example, the 4×C2 terminator or the gastrin terminator. Likewise, the vectors may utilize a diversity of RNA Pol II promoters different from the CMV promoter examples provided herein, for example, constitutive promoters such as the elongation factor 1 (EF1) promoter, the chicken β-actin promoter, the β-actin promoter from other species, the elongation factor-1α (EF1α) promoter, the phosphoglycerokinase (PGK) promoter, the Rous sarcoma virus (RSV) promoter, the human serum albumin (SA) promoter, the α-1 antitrypsin (AAT) promoter, the thyroxine binding globulin (TBG) promoter, the cytochrome P450 2E1 (CYP2E1) promoter, etc. The vectors may also utilize combination promoters such as the chicken β-actin/CMV enhancer (CAG) promoter, the human or murine CMV-derived enhancer elements combined with the elongation factor 1α (EF1α) promoters, CpG free versions of the human or murine CMV-derived enhancer elements combined with the elongation factor 1α (EF1α) promoters, the albumin promoter combined with an α-fetoprotein MERII enhancer, etc, or the diversity of tissue specific or inducible promoters know in the art such as the muscle specific promoters muscle creatine kinase (MCK), and C5-12 described herein or the liver-specific promoter apolipoprotein A-I (ApoAI).

Accordingly, the scope of the invention should be determined not by the embodiments illustrated, but by the appended claims. 

1-20. (canceled)
 21. A method for heat inducible production of a Rep protein dependent replication origin plasmid vector, comprising: a. cloning the plasmid replication regulating Rep protein into a expression vector to create a P_(L)—Rep protein expression cassette in which said Rep protein is expressed under the control of the P_(L) promoter; b. integrating said P_(L)—Rep protein expression cassette into a host strain genome to create a P_(L)—Rep protein host strain in which expression from the said P_(L)—Rep protein expression cassette is repressed by the temperature sensitive cI857 repressor; c. transforming said P_(L)—Rep protein host strain with said Rep protein dependent replication origin plasmid vector; d. isolating the resultant transformed bacterial cells; e. propagating said transformed bacterial cells at 25-32° C. to maintain the said Rep protein dependent plasmid vector at a basal copy number; and f. inducing said transformed bacterial cells at 37-42° C. to increase copy number of said Rep protein dependent plasmid vector.
 22. The method of claim 21, wherein said P_(L) promoter is selected from the group comprising a P_(L) promoter (SEQ ID NO: 10), P_(L) promoter OL1-G (SEQ ID NO: 11), and P_(L) promoter OL1-G to T (SEQ ID NO: 12).
 23. The method of claim 21, wherein said Rep protein dependent replication origin is selected from the group consisting of a R6K replication origin, ColE2-P9 replication origin and ColE2 related replication origin.
 24. The method of claim 21, wherein said plasmid replication regulating Rep protein comprises an R6K Rep protein mutation selected from the group consisting of P42L-P113S (SEQ ID NO: 13) and P42L-P106L-F107S (SEQ ID NO: 14).
 25. The method of claim 21, wherein said plasmid replication regulating Rep protein comprises a ColE2 Rep protein selected from the group consisting of ColE2 Rep protein (SEQ ID NO: 15) and ColE2 Rep protein mutation G194D (SEQ ID NO: 16).
 26. The method of claim 21, wherein said P_(L)—Rep protein host strain further comprises an RNA-IN regulated selection marker.
 27. The method of claim 21, wherein said Rep protein dependent plasmid vector for heat inducible production has a vector backbone with at least 95% sequence identity to a sequence selected from the group consisting of: SEQ ID NO: 2, SEQ ID NO: 3, SEQ ID NO: 8, SEQ ID NO: 9, SEQ ID NO: 39, SEQ ID NO: 40, SEQ ID NO:
 41. 28. A method for heat inducible production of a target protein or mRNA gene from the Escherichia coli genome, comprising: a. Cloning the said target protein or mRNA gene into an expression vector to create a P_(L)—target protein or P_(L)—mRNA gene expression cassette in which said target protein or mRNA gene is expressed under the control of the P_(L) promoter and said P_(L) promoter further comprises a OL1 mutation; b. Integrating said P_(L)—target protein or P_(L)—mRNA gene expression cassette into a host strain genome to create a P_(L)—target protein or P_(L)—mRNA host strain in which expression from the said P_(L)—target protein or P_(L)—mRNA gene expression cassette is repressed by the temperature sensitive cI857 repressor; c. propagating said P_(L)—target protein or P_(L)—mRNA host strain at 25-32° C. to maintain said target protein or mRNA at a basal copy number; and d. inducing said P_(L)—target protein or P_(L)—mRNA host strain at 37-42° C. to increase expression of said target protein or mRNA.
 29. The method of claim 28, wherein said P_(L) promoter OL1 mutation is selected from the group comprising P_(L) promoter OL1-G (SEQ ID NO: 11), and P_(L) promoter OL1-G to T (SEQ ID NO: 12).
 30. An isolated transformed bacterial host cell comprising: 1) a chromosomal gene which inhibits cell growth operably linked to a antisense sequence that is complementary to a portion of an RNA selectable marker; and 2) a eukaryotic replicative minicircle expression vector comprising i) eukaryotic region sequences comprising 5′ and 3′ ends; and ii) a spacer region of less than 500 basepairs in length linking the 5′ and 3′ ends of the eukaryotic region sequences and comprising a bacterial replication origin that is not the pUC origin and a RNA selectable marker that is complementary to said antisense sequence.
 31. The isolated transformed bacterial host cell according to claim 30, wherein said vector has at least 95% sequence identity to a sequence selected from the group consisting of: SEQ ID NO: 2, SEQ ID NO: 3, SEQ ID NO: 8, SEQ ID NO: 9, SEQ ID NO: 39, SEQ ID NO: 40, SEQ ID NO:
 41. 32. A method of manufacture comprising culturing the isolated transformed bacterial host cell according to claim 30 in culture media under conditions such that said transformed bacterial host cell manufactures vector in yields of greater than 100 mg vector per liter culture media.
 33. The method of claim 32, wherein said transformed bacterial host cell manufactures vector in yields up to 695 mg vector per liter culture media.
 34. The isolated transformed bacterial host cell according to claim 30, wherein said RNA selectable marker is selected from the group consisting of: an RNA-OUT selectable marker that encodes an RNA-IN regulating RNA-OUT RNA with at least 95% sequence identity to SEQ ID NO: 24; an RNAI selectable marker that encodes an RNAII regulating RNAI RNA with at least 95% sequence identity to SEQ ID NO: 31; an IncB RNAI selectable marker encoding an RNAII regulating RNAI RNA with at least 95% sequence identity to SEQ ID NO:
 33. 35. The isolated transformed bacterial host cell according to claim 30, wherein said bacterial replication origin is an R6K replication origin with at least 95% sequence identity to a sequence selected from the group consisting of: SEQ ID NO: 1, SEQ ID NO:
 22. 36. The isolated transformed bacterial host cell according to claim 30, wherein said bacterial replication origin is an ColE2-P9 replication origin with at least 95% sequence identity to a sequence selected from the group consisting of: SEQ ID NO: 4, SEQ ID NO: 5, SEQ ID NO: 6, SEQ ID NO: 7; SEQ ID NO:
 28. 